WO2020066801A1 - Air conditioning system - Google Patents

Abstract

A first air conditioner (AC) (9a), a second AC (9b), and a third AC (9c) that are independent from each other are provided as a plurality in an air-conditioned room. Individual target temperatures for each room as acquired from an input/output terminal (19) and an outdoor temperature acquired by an outdoor temperature sensor (7) are inputted to a mode setting unit (32). On the basis of the individual target temperatures and the outdoor temperature, the mode setting unit (32) sets a cooling mode and a cooling setting temperature for use during operation of the cooling mode, or sets a heating mode and a heating setting temperature for use during operation of the heating mode, for each of the first AC (9a), the second AC (9b), and the third AC (9c).

Description

Air conditioning system

The present invention relates to an air conditioning system.

2. Description of the Related Art Conventionally, in a highly insulated and airtight house having a plurality of living rooms, at least one air conditioning room is independently provided, and air conditioning in the air conditioning room is controlled by one air conditioner. 2. Description of the Related Art A whole building air-conditioning type air-conditioning system is known in which air-conditioning room air is individually distributed and supplied by being connected by an air supply duct (for example, Patent Document 1).

In such a conventional air-conditioning system, the temperature of the air-conditioning room is set according to the target temperature of each room, and the air conditioner is automatically operated to switch between the cooling mode and the heating mode in accordance with the target temperature. The air-conditioned room is air-conditioned to reach the temperature. This conventional air conditioning system does not require a dedicated air conditioner, and can realize air conditioning throughout the building without limiting the manufacturer of the air conditioner.

JP 2011-127845 A

However, when such a conventional air conditioning system is used in a season or a region where the temperature difference is severe throughout the day, the operation mode of the automatically operated air conditioner is frequently switched between a cooling mode and a heating mode, and the air conditioner is operated. May have a shorter lifespan. Switching between the cooling mode and the heating mode by the automatic operation of the air conditioner is performed according to the manufacturer of the air conditioner and the air conditioner itself. In the interim period when the conditions are almost the same, there is a problem that the operation of the air conditioner cannot be predicted. As described above, the whole building air-conditioning type air-conditioning system still has room for improvement in performing stable control.

The present invention has been made in view of the above circumstances, and an object of the present invention is to provide an air conditioning system capable of performing stable control.

Another object of the present invention is to provide an air conditioning system capable of efficient dehumidification.

To achieve this object, the air conditioning system of the present invention includes a plurality of air conditioners, a plurality of transport fans, a living room temperature sensor, an outdoor temperature sensor, an air conditioning room temperature sensor, a target temperature input receiving unit, A system controller. The plurality of air conditioners are provided in an air conditioning room and can be independently controlled. The plurality of transport fans transport the air in the air-conditioned room to a plurality of living rooms different from the air-conditioned room, and are provided for each of the plurality of living rooms. The living room temperature sensor acquires the temperature of each of the plurality of living rooms. The outdoor temperature sensor acquires an outdoor temperature. The air conditioning room temperature sensor acquires the temperature of the air conditioning room. The target temperature input receiving unit receives an input of an individual target temperature that is a target temperature of each of the plurality of living rooms. The system controller controls the air conditioner and the transport fan, and includes a blower volume determining unit, a mode setting unit, and a fan air volume controller. The air flow rate determination unit is configured to perform the individual transfer based on the individual target temperature acquired from the target temperature input reception unit, the temperature of each of the plurality of living rooms acquired by the living room temperature sensor, and the temperature of the air conditioning room acquired by the air conditioning room temperature sensor. Determine the air volume of the fan. The mode setting unit is configured to perform cooling mode and cooling setting for each of the plurality of independent air conditioners based on the individual target temperature acquired from the target temperature input reception unit and the outdoor temperature acquired by the outdoor temperature sensor. Set the temperature or the heating mode and the heating set temperature when the heating mode is operating. The fan air volume control unit blows the air in the air-conditioned room, which is air-conditioned based on the setting by the mode setting unit, independently to the living room with the air volume of the transport fan determined by the air volume determination unit.

The air conditioning system of the present invention includes a plurality of air conditioners provided in an air conditioning room and independently controllable, and a transfer fan for transferring air in the air conditioning room to a plurality of living rooms different from the air conditioning room. In addition, an air conditioner temperature sensor for obtaining the temperature of the air conditioner room, an air conditioner humidity sensor for obtaining the humidity of the air conditioner room, a target humidity input receiving unit for receiving an input of a target humidity of the living room, and a system controller for controlling the air conditioner And. The air conditioning system further includes a cooling mode for at least one of the plurality of independent air conditioners when the humidity of the air conditioning room obtained by the air conditioning room humidity sensor is higher than the target humidity obtained from the target humidity input reception unit. And, the cooling set temperature in the cooling mode operation is set to a temperature at which the air in the air conditioning room can be dehumidified based on the temperature of the air conditioning room acquired by the air conditioning room temperature sensor and the humidity of the air conditioning room acquired by the air conditioning room humidity sensor. A mode setting unit configured to set a heating mode and a heating set temperature during a heating mode operation for at least one other air conditioner other than the air conditioner set to the cooling mode.

According to the air conditioning system of the present invention, based on the individual target temperature of each of the plurality of living rooms obtained from the target temperature input receiving unit and the outdoor temperature obtained by the outdoor temperature sensor, cooling is performed for each of the plurality of independent air conditioners. The mode setting unit sets a cooling set temperature in the mode and the cooling mode operation or a heating set temperature in the heating mode and the heating mode operation. Then, the air in the air-conditioned room, which is air-conditioned based on the setting by the mode setting unit, is blown independently to the living room by the mode air flow control unit with the air flow of the transport fan determined by the air flow determination unit. As a result, the cooling mode and the cooling set temperature or the heating mode and the heating set temperature are set independently for a plurality of air conditioners, so that the air conditioning of the air conditioning room can be stably controlled without using the automatic operation of the air conditioners. it can. Therefore, there is an effect that an air conditioning system capable of performing stable control can be provided.

Also, there is an effect that dehumidification of the air conditioning room can be realized without providing a dehumidifier.

FIG. 1 is a schematic connection diagram of the ventilation air conditioning system according to the first embodiment of the present invention. FIG. 2 is a schematic functional block diagram of a system controller of the ventilation and air conditioning system. FIG. 3 is a flowchart showing a mode setting process executed by the system controller. FIG. 4 is a flowchart showing a mode determination process executed by the system controller. FIG. 5 is a flowchart showing the air volume determination process executed by the system controller. FIG. 6 is a flowchart illustrating a mode determination process executed by the system controller of the ventilation and air conditioning system according to the second embodiment of the present invention. FIG. 7 is a flowchart illustrating a mode determination process executed by the system controller of the ventilation and air conditioning system according to the third embodiment of the present invention. FIG. 8 is a flowchart showing the air volume determining process executed by the system controller. FIG. 9 is a flowchart illustrating a mode determination process executed by the system controller of the ventilation and air conditioning system according to the fourth embodiment of the present invention. FIG. 10 is a flowchart illustrating a mode determination process executed by the system controller of the ventilation and air conditioning system according to the fifth embodiment of the present invention. FIG. 11 is a flowchart illustrating a mode determination process executed by the system controller of the ventilation and air conditioning system according to the sixth embodiment of the present invention.

Hereinafter, embodiments for carrying out the present invention will be described with reference to the accompanying drawings. It should be noted that each of the embodiments described below shows a preferred specific example of the present invention. Therefore, the numerical values, shapes, materials, constituent elements, the arrangement positions and connection forms of the constituent elements, the steps (processes) and the order of the steps, and the like shown in the following embodiments are examples and limit the present invention. It is not the main purpose. Therefore, among the components in the following embodiments, components that are not described in the independent claims that indicate the highest concept of the present invention are described as arbitrary components. In addition, in each of the drawings, substantially the same configuration is denoted by the same reference numeral, and redundant description will be omitted or simplified.

(1st Embodiment)
First, a ventilation air conditioning system 20 according to a first embodiment, which is an embodiment of the air conditioning system of the present invention, will be described with reference to FIG. FIG. 1 is a schematic connection diagram of the ventilation air conditioning system 20 according to the first embodiment.

The ventilation air conditioning system 20 includes an outside air introduction fan 4, a plurality of exhaust fans 5a, 5b, 5c, 5d, a plurality of transport fans 3a, 3b, 3c, 3d, and a plurality of circulation fans 6a, 6b, 6c, 6d. Outdoor temperature sensor 7, living room temperature sensors 11a, 11b, 11c, 11d, living room humidity sensors 12a, 12b, 12c, 12d, air conditioning room temperature sensor 14, air conditioning room humidity sensor 15, and a plurality of air conditioners 9a. , 9b, 9c, a humidifier 16, a dehumidifier 17, an input / output terminal 19, and a system controller 10.

The ventilation air conditioning system 20 is installed in the general house 1 which is an example of a building. The general house 1 has a plurality of (four in the present embodiment) rooms 2a to 2d and at least one air-conditioning room 18 independent of the rooms 2a to 2d. Here, the general house 1 (house) is a house provided as a place where the resident performs a private life, and the room generally includes a living room, a dining room, a bedroom, a private room, a child room, and the like. . Further, the living room provided by the ventilation and air conditioning system 20 may include a toilet, a bathroom, a washroom, a dressing room, and the like.

In the air-conditioning room 18, outside air is taken into the air-conditioning room 18 by the outside air introduction fan 4, and mixed with the air carried from each of the living rooms 2a to 2d by the circulation fans 6a to 6d. The air in the air conditioning room 18 is air-conditioned by controlling the temperature and humidity by a plurality (three in this embodiment) of air conditioners 9 a to 9 c, a humidifier 16 and a dehumidifier 17 provided in the air conditioning room 18. You. The air conditioned in the air conditioning room 18 is conveyed to the living rooms 2a to 2d by the conveyance fans 3a to 3d. That is, the entire building is air-conditioned by the ventilation and air-conditioning system 20 for the general house 1.

The air in each of the living rooms 2a to 2d is conveyed to the air-conditioning room 18 by the circulation fans 6a to 6d, and is discharged from the inside of the rooms 2a to 2d to the outside of the general house 1 as outside air by the exhaust fans 5a to 5d. The ventilation air-conditioning system 20 controls the amount of exhaust air from the exhaust fans 5a to 5d to discharge outside air from the room, and controls the amount of air supplied to the outside air introduction fan 4 in conjunction with the amount of exhaust air from the exhaust fans 5a to 5d. By taking in outside air into the room, ventilation of the first type ventilation system is performed.

(4) The outside air introduction fan 4 is a fan that takes in outside air into the room of the general house 1, and corresponds to an air supply fan or a heat exchange air fan. As described above, the outside air taken in by the outside air introduction fan 4 is introduced into the air conditioning room 18. The supply air volume of the outside air introduction fan 4 is configured to be set in a plurality of stages, and the exhaust air volume is set according to the exhaust air volumes of the exhaust fans 5a to 5d.

(4) The exhaust fans 5a to 5d are fans that discharge a part of the air in the corresponding living rooms 2a to 2d as outside air, and correspond to the exhaust function of a ceiling-mounted ventilation fan, a wall-mounted ventilation fan, a range hood, a heat exchange air fan, and the like. The exhaust fan 5a is provided in the living room 2a, the exhaust fan 5b is provided in the living room 2b, the exhaust fan 5c is provided in the living room 2c, and the exhaust fan 5d is provided in the living room 2d.

排 気 Each of the exhaust fans 5a to 5d is configured such that the exhaust air volume can be set in a plurality of stages. At normal times, the exhaust fans 5a to 5d are controlled so as to have a preset exhaust air volume. Then, the exhaust air volume is controlled for each of the exhaust fans 5a to 5d according to the settings made by the user and the values obtained by the various sensors.

The transport fans 3a to 3d are provided in the air-conditioning room 18 corresponding to the living rooms 2a to 2d. The air in the air-conditioned room 18 is transported to the living room 2a by the transport fan 3a, transported to the living room 2b by the transport fan 3b, transported to the living room 2c by the transport fan 3c, and transported to the living room 2d by the transport fan 3d.

The circulation fan 6a is provided in the living room 2a, the circulation fan 6b is provided in the living room 2b, the circulation fan 6c is provided in the living room 2c, and the circulation fan 6d is provided in the living room 2d. A part of the air in each of the living rooms 2a to 2d is conveyed to the air conditioning room 18 by the corresponding circulation fans 6a to 6d.

The air conditioners 9a to 9c correspond to air conditioners, and include a first air conditioner (hereinafter, referred to as "first AC") 9a, a second air conditioner (hereinafter, referred to as "second AC") 9b, and a third air conditioner. A plurality of air conditioners with an air conditioner (hereinafter, referred to as "third AC") 9c control air conditioning of the air conditioning room 18. As the air conditioners 9a to 9c, general-purpose products can be used. Here, the general-purpose product is not developed exclusively for the air-conditioning system according to the present invention or has not been adjusted in operation, but is sold separately from the air-conditioning system and can air-condition a living room by itself. Air conditioner.

The first AC 9a, the second AC 9b, and the third AC 9c can be independently controlled, and the cooling mode or the heating mode is individually set as the operation mode. Further, the first AC 9a, the second AC 9b, and the third AC 9c each have a cooling set temperature during the cooling mode operation when the cooling mode is set, and a heating set temperature during the heating mode operation when the heating mode is set. Is set.

(4) The air conditioner set to the cooling mode as the operation mode cools the air in the air conditioning room 18 so that the air conditioning room 18 has the cooling set temperature. The air conditioner set to the heating mode as the operation mode heats the air in the air conditioning room 18 so that the air conditioning room 18 has the heating set temperature.

In the present invention, the number of air conditioners provided in one air conditioning room 18 may be a plurality, and the number is not limited to three.

The humidifier 16 humidifies the air in the air conditioning room 18 so that when the humidity of the air in the air conditioning room 18 is lower than the set target humidity (air conditioning room target humidity), the humidity becomes the air conditioning room target humidity.

The dehumidifier 17 dehumidifies the air in the air conditioning room 18 so that when the humidity of the air in the air conditioning room 18 is higher than the set target humidity (air conditioning room target humidity), the humidity becomes the air conditioning room target humidity.

The outdoor temperature sensor 7 is a sensor that is provided outside the general house 1 and acquires the outdoor temperature and transmits the acquired temperature to the system controller 10.

The living room temperature sensor 11a is provided in the living room 2a, the living room temperature sensor 11b is provided in the living room 2b, the living room temperature sensor 11c is provided in the living room 2c, and the living room temperature sensor 11d is provided in the living room 2d. The room temperature sensors 11a to 11d are sensors that acquire the room temperature of each of the corresponding room 2a to 2d and transmit the acquired room temperature to the system controller 10.

The room humidity sensor 12a is provided in the room 2a, the room humidity sensor 12b is provided in the room 2b, the room humidity sensor 12c is provided in the room 2c, and the room humidity sensor 12d is provided in the room 2d. The living room humidity sensors 12a to 12d are sensors that acquire the room humidity of each of the corresponding living rooms 2a to 2d and transmit them to the system controller 10.

The air conditioner temperature sensor 14 is a sensor that acquires the temperature of the air in the air conditioner room 18 and transmits the temperature to the system controller 10. The air conditioning room humidity sensor 15 is a sensor that acquires the humidity of the air in the air conditioning room 18 and transmits the acquired humidity to the system controller 10.

The system controller 10 is a controller that controls the entire ventilation and air conditioning system 20. The system controller 10 includes an outside air introduction fan 4, exhaust fans 5a to 5d, transport fans 3a to 3d, circulation fans 6a to 6d, outdoor temperature sensor 7, room temperature sensors 11a to 11d, room humidity sensors 12a to 12d, and air conditioning room temperature. The sensor 14, the air conditioning room humidity sensor 15, the first AC 9a, the second AC 9b, the third AC 9c, the humidifier 16, and the dehumidifier 17 are communicably connected to each other by wireless communication.

The system controller 10 operates the outside air introduction fan 4 and the exhaust fans 5a to 5d in an interlocked manner, such as setting the air supply amount of the outside air introduction fan 4 so that the air flow is adjusted according to the exhaust air amount of the exhaust fans 5a to 5d. Control. Thereby, the general house 1 is ventilated by the first type ventilation system.

Further, the system controller 10 controls the independent first AC 9a, second AC 9b, and third AC 9c based on the individual target temperature, which is the target temperature of each of the living rooms 2a to 2d, and the outdoor temperature acquired by the outdoor temperature sensor 7. On the other hand, a cooling mode or a heating mode is set as an operation mode, and a cooling set temperature or a heating set temperature is set together. Thereby, the operation of each of the first AC 9a, the second AC 9b, and the third AC 9c controls the temperature of the air in the air-conditioned room 18 to be a temperature according to the cooling set temperature and / or the heating set temperature.

The system controller 10 also sets the humidity of the air conditioning room 18 based on the humidity of the air in the air conditioning room 18 acquired by the air conditioning room humidity sensor 15 so that the humidity of the air conditioning room 18 becomes the air conditioning room target humidity set in the air conditioning room 18. The humidifier 16 and the dehumidifier 17 are controlled.

Further, the system controller 10 controls the room temperature and / or room humidity of each of the rooms 2a to 2d obtained by the room temperature sensors 11a to 11d and the room humidity sensors 12a to 12d, and the target temperature set for each of the rooms 2a to 2d. The transport fan 3a according to (individual target temperature) and / or target humidity (individual target humidity) and the temperature and / or humidity of the air in the air conditioning room 18 acquired by the air conditioning room temperature sensor 14 and the air conditioning room humidity sensor 15. 3d and the air volume of the circulation fans 6a to 6d are set.

As a result, the air conditioned in the air-conditioning room 18 is conveyed to each of the living rooms 2a to 2d with the air volume set for each of the conveying fans 3a to 3d, and the air in each of the living rooms 2a to 2d is conveyed to each of the circulation fans 6a. The air is conveyed to the air conditioning room 18 with the air volume set to 6 d. Therefore, the room temperature and / or room humidity of each of the living rooms 2a to 2d is controlled to be the individual target temperature and / or the individual target humidity.

Here, the system controller 10, the outside air introduction fan 4, the exhaust fans 5a to 5d, the transport fans 3a to 3d, the circulation fans 6a to 6d, the outdoor temperature sensor 7, the room temperature sensors 11a to 11d, the room humidity sensors 12a to 12d, The air conditioning room temperature sensor 14, the air conditioning room humidity sensor 15, the first AC 9a, the second AC 9b, the third AC 9c, the humidifier 16 and the dehumidifier 17 are connected by wireless communication, thereby making complicated wiring work unnecessary. it can. However, the whole thereof, or the system controller 10 and a part thereof may be configured to be communicable by wired communication.

The input / output terminal 19 is communicably connected to the system controller 10 by wireless communication. The input / output terminal 19 receives input of information necessary for constructing the ventilation air conditioning system 20 and stores the information in the system controller 10. Is acquired from the system controller 10 and displayed.

個別 The individual target temperature which is the target temperature of each of the living rooms 2a to 2d is input from the input / output terminal 19. The input / output terminal 19 corresponds to a target temperature input receiving unit and a target humidity input receiving unit. The input / output terminal 19 is, for example, a mobile information terminal such as a mobile phone, a smartphone, or a tablet.

The input / output terminal 19 does not necessarily need to be connected to the system controller 10 by wireless communication, and may be connected to the system controller 10 so as to be able to communicate by wire communication. In this case, the input / output terminal 19 may be realized by a wall-mounted remote controller, for example.

The input / output terminal 19 may be configured by a plurality of independent terminals, or may be configured such that information that can be input or output at each terminal is different. For example, a wall-mounted remote controller may be provided in each of the living rooms 2a to 2d, and the target temperature (individual target temperature) of the corresponding living room may be set by each remote controller.

Next, each function of the system controller 10 will be described with reference to FIG. FIG. 2 is a schematic functional block diagram of the system controller 10.

The system controller 10 has at least an air volume determining unit 31, a mode setting unit 32, and a fan air volume control unit 33.

(4) The air volume determining unit 31 determines the air volume of each of the transport fans 3a to 3d provided in the air conditioning room 18. The individual target temperature of each of the plurality of living rooms 2a to 2d acquired from the input / output terminal 19 is input to the blower amount determining unit 31. The temperature of the plurality of living rooms 2a to 2d acquired by the living room temperature sensors 11a to 11d is input to the blower amount determining unit 31. Further, the temperature of the air-conditioned room 18 acquired by the air-conditioned room temperature sensor 14 is input to the blower amount determining unit 31.

Then, the air volume determining unit 31 determines each of the rooms based on the temperature of the corresponding room and the temperature of the air-conditioned room 18 so that the temperature of each of the rooms 2a to 2d becomes the individually set target temperature. The air blowing amounts of the transport fans 3a to 3d corresponding to 2a to 2d are individually determined. The details of the air volume determining unit 31 will be described later with reference to FIG.

The mode setting unit 32 controls the cooling set temperature in the cooling mode and the cooling mode operation or the cooling set temperature in the heating mode and the heating mode operation for each of the plurality of independent first AC 9a, second AC 9b, and third AC 9c provided in the air conditioning room 18. Set the heating set temperature. The mode setting unit 32 receives the individual target temperature of each of the plurality of living rooms 2 a to 2 d obtained from the input / output terminal 19 and the outdoor temperature outside the general house 1 obtained by the outdoor temperature sensor 7.

The 設定 mode setting unit 32 sets an operation mode and a set temperature for each of the first AC 9a, the second AC 9b, and the third AC 9c based on the input individual target temperature and outdoor temperature. The details of the mode setting unit 32 will be described later with reference to FIGS.

The fan air volume control unit 33 controls the air blowing by each of the transport fans 3a to 3d. Specifically, the fan air volume control unit 33 controls the air in the air-conditioning room 18 to be independently blown to each of the living rooms 2a to 2d with the air volume of the transport fans 3a to 3d determined by the air volume determination unit 31. I do. Thereby, the air in the air-conditioned room 18 air-conditioned by the first AC 9a, the second AC 9b, and the third AC 9c based on the setting by the mode setting unit 32 is supplied to the respective living rooms 2a to 2d at the air flow rates determined according to the respective living rooms 2a to 2d. It is sent to 2d. Therefore, the ventilation air conditioning system 20 is controlled so that the room temperature of each of the living rooms 2a to 2d becomes the individually set target temperature.

Next, a mode setting process performed by the system controller 10 will be described with reference to FIGS. First, FIG. 3 is a flowchart showing the mode setting process.

This mode setting process is executed by the system controller 10 every predetermined time (for example, every one hour). In addition, the mode setting process may be executed even when the individual target temperature of any of the rooms 2a to 2d is changed from the input / output terminal 19 by the user.

The system controller 10 configures the mode setting unit 32 (see FIG. 2) by executing the mode setting process.

When executing the mode setting process, the system controller 10 first obtains the maximum set temperature CRmax and the minimum set temperature CRmin that are the maximum value and the minimum value of the range of the individual target temperature that can be set for the living rooms 2a to 2d ( S11). The maximum set temperature CRmax and the minimum set temperature CRmin may be stored in advance in a storage unit provided in the system controller 10 or may be stored in the storage unit of the input / output terminal 19. Good.

Next, the system controller 10 acquires the individual target temperatures set for each of the living rooms 2a to 2d from the input / output terminal 19 constituting the target temperature input receiving unit (S12). Next, the system controller 10 acquires the current outdoor temperature Tout acquired by the outdoor temperature sensor 7 (S13).

Next, the system controller 10 calculates the maximum target temperature Tmax, which is the maximum value of the individual target temperatures of each of the living rooms 2a to 2d acquired in the process of S12, and the minimum target temperature Tmin, which is the minimum value of the individual target temperatures. (S14).

Then, the system controller 10 executes a mode determination process (S15). In the mode determination processing, the maximum set temperature CRmax and the minimum set temperature CRmin obtained in the processing of S11, the outdoor temperature Tout obtained in the processing of S13, and the maximum target temperature Tmax and the minimum target temperature Tmin calculated in the processing of S14 are calculated. Therefore, the operation mode and the set temperature are set for each of the first AC 9a, the second AC 9b, and the third AC 9c in the air-conditioned room 18. Details of the mode determination processing will be described later with reference to FIG.

After executing the mode determination processing of S15, the system controller 10 transmits the operation mode and the set temperature set respectively to the first AC 9a, the second AC 9b, and the third AC 9c (S16), and ends the mode setting processing. . Accordingly, the first AC 9a, the second AC 9b, and the third AC 9c respectively include the maximum set temperature CRmax and the minimum set temperature CRmin, the current outdoor temperature Tout, and the maximum target temperature Tmax of the individual target temperature set in each of the living rooms 2a to 2d. The air conditioner 18 is air-conditioned in the operation mode and the set temperature set according to the minimum target temperature Tmin.

Here, with reference to FIG. 4, details of the mode determination process (S15) executed by the system controller 10 in the mode setting process will be described. FIG. 4 is a flowchart showing the mode determination processing.

When the system controller 10 executes the mode setting process, first, the current outdoor temperature Tout is lower than Tmax + α, which is the first threshold value obtained by adding α degrees (α is a real number equal to or more than 0) to the maximum target temperature Tmax. It is determined whether it is higher than Tmin-β, which is a second threshold value obtained by subtracting β degrees (β is a real number equal to or greater than 0) from Tmin (S21). The parameters α and β may be values stored in the system controller 10 in advance, or may be configured to be changeable from the input / output terminal 19 by a user or an installer.

In the process of S21, it may be determined whether or not the current outdoor temperature Tout is equal to or lower than the first threshold Tmax + α instead of whether or not the current outdoor temperature Tout is lower than the first threshold Tmax + α. Further, in the process of S21, it may be determined whether or not the current outdoor temperature Tout is equal to or higher than the second threshold value Tmin-β, instead of determining whether or not the current outdoor temperature Tout is higher than the second threshold value Tmin-β. .

If the current outdoor temperature Tout is substantially the same as one of the maximum target temperature Tmax and the minimum target temperature Tmin, or is within the range of the maximum target temperature Tmax and the minimum target temperature Tmin, even in the cooling period in which each of the living rooms 2a to 2d is cooled. It is considered to be an intermediate period which is not a heating period for heating each of the living rooms 2a to 2d.

Therefore, as a result of the processing in S21, when it is determined that the current outdoor temperature Tout is lower than the first threshold and higher than the second threshold (S21: Yes), the system controller 10 determines that the current period is an intermediate period, and The processing of S22 and S23 is executed so that the air conditioning suitable for the intermediate period is performed on 18.

Specifically, in the process of S22, the system controller 10 sets the operation mode of the first AC 9a and the second AC 9b to the cooling mode. In the same process, the system controller 10 sets the cooling target temperature at the time of the cooling mode operation to a temperature obtained by adding ψ degrees (ψ is a real number equal to or greater than 0) to the maximum target temperature Tmax.

In the subsequent process of S23, the system controller 10 sets the operation mode of the third AC 9c to the heating mode. In the same process, the system controller 10 sets, as the heating set temperature during the heating mode operation, a temperature obtained by subtracting ω degrees (ω is a real number equal to or greater than 0) from the minimum target temperature Tmin.

Note that the parameters ψ and ω may be values stored in the system controller 10 in advance, or may be configured to be changeable from the input / output terminal 19 by a user or an installer.

In the mode determination process, it is desirable that the determination of the mode, that is, the determination of the cooling period, the heating period, and the intermediate period be performed, for example, around the time when the outside air temperature is highest throughout the day. In the Northern Hemisphere, the time at which the outside air temperature is highest is, for example, a time that has elapsed about two to three hours from the southern middle time when the sun is farthest from the horizon. In the southern hemisphere, although it is exactly the northern middle time, this is also expressed as the southern middle time. In consideration of the influence of weather conditions, it is preferable that the mode determination processing is performed within a range of about four hours before and after the south middle time. Thereby, in the case of Japan, for example, in the middle period in which the outside air temperature in the morning is about 12 degrees and the outside air temperature in the daytime is about 24 degrees, the mode determination process is performed in the morning and the heating period is determined. Can be prevented. In this case, if it is outside the target time, the mode determination process during the mode setting process is canceled in FIG.

の 後 After the processing in S23, the system controller 10 ends the mode determination processing and returns to the mode setting processing.

By the processing of S22 and S23, if the temperature of the air conditioning room 18 is higher than the cooling setting temperature Tmax + ψ in the intermediate period, the air conditioning room 18 is cooled by the first AC 9a and the second AC 9b so that the temperature of the air conditioning room 18 becomes equal to or lower than the cooling setting temperature Tmax + ψ. You. If the temperature of the air conditioning room 18 is lower than the heating set temperature Tmin-ω, the third AC 9c heats the air conditioning room 18 so that the temperature of the air conditioning room 18 becomes equal to or higher than the heating set temperature Tmin-ω.

Therefore, the temperature of the air-conditioning room 18 is maintained between the heating set temperature Tmin-ω and the cooling set temperature Tmax + ψ, whereby the ventilation air-conditioning system 20 sets the temperature of each of the living rooms 2a to 2d to at least the heating setting in the intermediate period. It can be within the range of the temperature Tmin-ω and the cooling set temperature Tmax + ψ. Therefore, the operation of the ventilation and air conditioning system 20 can be predicted, and stable control can be performed.

When the outdoor temperature Tout is within the range between the heating set temperature Tmin-ω and the cooling set temperature Tmax + ψ, the system controller 10 exhausts air from the exhaust fans 5a to 5d and introduces outside air from the outside air introduction fan 4. By performing ventilation, the temperature of the air conditioning room 18 can be set to the outdoor temperature Tout.

In other words, if a large amount of ventilation is performed when the outdoor temperature Tout is higher than the maximum target temperature Tmax or lower than the minimum target temperature Tmin, the load on the air conditioner increases, and energy is not saved. On the other hand, when the outdoor temperature Tout is in the range from the minimum target temperature Tmin to the maximum target temperature Tmax, no load is applied to each air conditioner even in full ventilation, so that ventilation and temperature control can be compatible with energy saving. .

For this reason, if the outdoor temperature Tout is in the range from the minimum target temperature Tmin to the maximum target temperature Tmax in the case where it is determined that the outdoor temperature Tout is in the middle period, the outdoor temperature Tout becomes higher than the maximum target temperature Tmax. It is preferable to increase the amount of outside air introduced into the air-conditioning room 18 by the outside air introduction fan 4 as compared with the case where the temperature is high or lower than the minimum target temperature Tmin.

{Thus, the ventilation air-conditioning system 20 can set the temperature of each living room 2a to 2d to the outdoor temperature Tout within the range of the heating set temperature Tmin-ω and the cooling set temperature Tmax + ψ. In this case, since the first AC 9a, the second AC 9b, and the third AC 9c can all be in a stopped state, the load on each of the air conditioners 9a to 9c is reduced, and energy saving and a long life of the air conditioners 9a to 9c are achieved. Can be.

In the processing of S22 and S23, in the interim period, the cooling set temperature in the cooling mode and the cooling mode operation is set for the first AC 9a and the second AC 9b, and the heating mode and the heating mode in the heating mode operation are set for the third AC 9c. The case of setting the set temperature has been described. However, among the plurality of air conditioners 9a to 9c, at least one of the air conditioners 9a to 9c sets the cooling mode and the cooling set temperature in the cooling mode operation, and the other at least one sets the heating mode and the heating set temperature in the heating mode operation. By setting, the same operation and effect as in the first embodiment can be obtained.

Here, when the operation mode and the set temperature of each of the air conditioners 9a to 9c are set by the processing of S22 and S23, the temperature of the air-conditioned room 18 is a predetermined value within a range between the heating set temperature Tmin-ω and the cooling set temperature Tmax + ψ. Temperature. Therefore, in this case, it is difficult for the ventilation air conditioning system 20 to control each of the living rooms 2a to 2d such that the temperature of the living room becomes an individual target temperature that can be set in a wide temperature range. Thus, the ventilation air conditioning system 20 controls the air flow of the transport fans 3a to 3d to change the sensible temperature. The details will be described in a blower amount determination process described later with reference to FIG.

On the other hand, when it is determined that the current outdoor temperature Tout is equal to or higher than the first threshold value or equal to or lower than the second threshold value as a result of the processing in S21 (S21: No), the system controller 10 executes the processing in S24 and The determination processing ends, and the processing returns to the mode setting processing.

In the process of S24, the system controller 10 operates the first AC 9a, the second AC 9b, and the third AC 9c based on the relationship among the outdoor temperature Tout, the maximum set temperature CRmax, the maximum target temperature Tmax, the minimum target temperature Tmin, and the minimum set temperature CRmin. Set the mode and set temperature. Thereby, the ventilation air conditioning system 20 can stably control the air conditioning of the air conditioning room 18 without using the automatic operation of each of the air conditioners 9a to 9c. Therefore, it is possible to provide the ventilation air conditioning system 20 that can perform stable control.

Next, with reference to FIG. 5, a description will be given of the air volume determination process performed by the system controller 10. FIG. 5 is a flowchart showing the air volume determination processing.

風 This air volume determination processing is executed by the system controller 10 every second predetermined time (for example, 10 minutes). The system controller 10 configures the air volume determining unit 31 (see FIG. 2) by executing the air volume determining process.

When the system controller 10 executes the air volume determination processing, first, it is determined whether or not the intermediate period has been determined by the processing in S21 of the mode determination processing (see FIG. 4) (S31). As a result, when it is determined that the period is the intermediate period (S31: Yes), the system controller 10 then sets the individual target temperature set in one of the rooms 2a to 2d to the temperature of the air-conditioned room 18 (air-conditioning). It is determined whether the temperature is lower than a third threshold value obtained by subtracting γ degrees (γ is a real number equal to or greater than 0) from the room temperature (S32). The parameter γ may be a value stored in the system controller 10 in advance, or may be configured to be changeable from the input / output terminal 19 by a user or an installer.

In the process of S32, instead of determining whether the individual target temperature is lower than the third threshold, it may be determined whether the individual target temperature is equal to or lower than the third threshold.

As a result of the processing in S32, when it is determined that the individual target temperature set in one living room is lower than the third threshold value (S32: Yes), the system controller 10 selects one of the transport fans 3a to 3d. The air blowing amount of the transport fan corresponding to the living room is set to "large" (S33).

The case where the individual target temperature set for the one living room is lower than the third threshold value indicates the case where the individual target temperature is lower than the temperature of the air conditioning room 18. It cannot be lower than the temperature. However, by setting the air blowing amount of the transport fan in the first room to “large” by the processing in S33, a large wind flow occurs in the room, and the perceived temperature can be reduced. Therefore, the user can experience a desired temperature.

In addition, setting the air flow rate of the transport fan to “large” means that, of the air flow rates of a plurality of stages that can be set in the transport fan, the air flow rate that is larger than the average value or the median value of the air flow rate is set. means. When there are a plurality of airflows larger than the average value or the median of the airflows, the larger the difference between the temperature of the air conditioning room 18 and the individual target temperature, the larger the airflow is set as the airflow of the corresponding transport fan. What should I do?

On the other hand, when it is determined that the individual target temperature set in one room is equal to or higher than the third threshold as a result of the process in S32 (S32: No), the system controller 10 then sets the one room. It is determined whether the obtained individual target temperature is higher than a fourth threshold value obtained by adding δ degrees (δ is a real number equal to or greater than 0) from the temperature of the air conditioning room 18 (air conditioning room temperature) (S34). The parameter δ may be a value stored in the system controller 10 in advance, or may be configured to be changeable from the input / output terminal 19 by a user or an installer.

In the process of S34, instead of determining whether the individual target temperature is higher than the fourth threshold, it may be determined whether the individual target temperature is equal to or higher than the fourth threshold.

As a result of the processing in S34, when it is determined that the individual target temperature set in one living room is higher than the fourth threshold value (S34: Yes), the system controller 10 selects one of the transport fans 3a to 3d. The air blowing amount of the transport fan corresponding to the living room is set to "small" (S35).

The case where the individual target temperature set for one living room is higher than the fourth threshold value indicates the case where the individual target temperature is higher than the temperature of the air conditioning room 18. It cannot be higher than the temperature. However, by setting the amount of air blown by the transfer fan in the first room to “small” by the processing of S35, the flow of air in the room can be suppressed, and the perceived temperature can be increased. Therefore, the user can experience a desired temperature.

In addition, setting the air flow rate of the transport fan to “small” means that, of the air flow rates of a plurality of stages that can be set in the transport fan, the air flow rate that is smaller than the average value or the median value of the air flow rate is set. means. When there are a plurality of airflows smaller than the average value or the median of the airflows, the smaller the airflow between the temperature of the air conditioning room 18 and the individual target temperature, the smaller the airflow is set as the airflow of the corresponding transport fan. What should I do?

On the other hand, as a result of the processing in S34, when it is determined that the individual target temperature set for one living room is equal to or less than the fourth threshold value (S34: No), the individual target temperature of the one living room is the air-conditioning room temperature. Is substantially the same as In this case, since the ventilation air conditioning system 20 can make the temperature of the one room close to the individual target temperature, the system controller 10 sends the transfer fan of the transfer fan corresponding to the one room among the transfer fans 3a to 3d. The air volume is set to "medium" (S36). Thereby, the ventilation air-conditioning system 20 can suppress the rise or fall of the perceived temperature and allow the user to feel the temperature just right.

Note that setting the air flow rate of the transfer fan to “medium” means that the air flow rate that is close to the average value of the air flow rate or the air flow rate that is the median value is set among the air flow rates of multiple stages that can be set for the transport fan. Means to do.

After executing the processing of S33, S35 or S36, the system controller 10 then determines whether or not the air blowing amounts of the corresponding transport fans 3a to 3d have been set for all the living rooms 2a to 2d (S37). As a result, when there is a room in which the air blowing amount of the transport fans 3a to 3d is not set (S37: No), the system controller 10 returns to the process of S32. Then, the system controller 10 executes the processing of S32 to S36 for one living room in which the air blowing amount of the transport fans 3a to 3d is not set.

On the other hand, as a result of the processing in S37, when it is determined that the air blowing amounts of the corresponding transport fans 3a to 3d have been set for all the living rooms 2a to 2d (S37: Yes), the system controller 10 performs the air blowing amount determination processing. finish.

Also, as a result of the processing in S31, when it is determined that the current period is not the intermediate period (S31: No), the individual target temperatures of the rooms 2a to 2d, the current temperatures of the rooms 2a to 2d, and the air conditioning room 18 Based on the temperature, the air blowing amount of each of the transport fans 3a to 3d corresponding to each of the living rooms 2a to 2d is set (S38).

For example, in a case where the current temperature of the one room is higher than the individual target temperature set in the one room, the condition is that the temperature of the air-conditioned room 18 is lower than the current temperature. Set a large amount of air to be blown by the transfer fan. In addition, the air blowing amount is set to increase as the difference between the individual target temperature and the current temperature of the living room increases. On the other hand, in this case, if the temperature of the air-conditioning room 18 is higher than the current temperature of the one living room, the air blowing amount of the corresponding transport fan is set to zero, and the temperature of the one living room is prevented from further increasing. .

When the current temperature of the one room is lower than the individual target temperature set for the one room in the one room, the condition is that the temperature of the air-conditioned room 18 is higher than the current temperature. Set a large amount of air to be blown by the transfer fan. In addition, the air blowing amount is set to increase as the difference between the individual target temperature and the current temperature of the living room increases. On the other hand, in this case, if the temperature of the air-conditioning room 18 is lower than the current temperature of the one living room, the air blowing amount of the corresponding transport fan is set to zero, and the temperature of the one living room is suppressed from lowering further. .

After the process in step S38, the system controller 10 ends the air volume determination process.

As described above, in the ventilation / air-conditioning system 20 according to the first embodiment, the plurality of living rooms 2 a to 2 d acquired from the input / output terminal 19 and the individual target temperatures acquired by the outdoor temperature sensor 7 and the plurality of outdoor temperatures are used. For each of the independent air conditioners 9a to 9c, the mode setting unit 32 sets the cooling set temperature in the cooling mode and the cooling mode operation or the heating set temperature in the heating mode and the heating mode operation.

The air in the air-conditioned room 18, which is air-conditioned based on the setting by the mode setting unit 32, is the air volume of the transport fans 3 a to 3 d determined by the air volume determining unit 31, and is controlled by the fan air volume control unit 33. It is blown independently to 2d.

As a result, the cooling mode and the cooling set temperature or the heating mode and the heating set temperature are set independently for the plurality of air conditioners 9a to 9c, so that the air conditioning room 18 does not use the automatic operation of the air conditioners 9a to 9c. Air conditioner can be controlled stably. Therefore, it is possible to provide the ventilation air conditioning system 20 that can perform stable control.

In particular, in the ventilation air-conditioning system 20 according to the first embodiment, when it is determined that the period is an intermediate period based on the individual target temperature and the outdoor temperature of each of the living rooms 2a to 2d, the cooling mode is set for the first AC 9a and the second AC 9b. , And Tmax + ψ is set as the cooling set temperature during the cooling mode operation. Further, the heating mode is set for the third AC 9c, and Tmin-ω is set as the heating set temperature during the heating mode operation.

As a result, in the intermediate period, the temperature of the air conditioning room 18 is maintained between the heating set temperature Tmin-ω and the cooling set temperature Tmax + ψ, so that the ventilation air conditioning system 20 sets the temperature of each of the living rooms 2a to 2d in the intermediate period. Can be at least within the range of the heating set temperature Tmin-ω and the cooling set temperature Tmax + ψ. Therefore, the operation of the ventilation and air conditioning system 20 can be predicted, and stable control can be performed.

Since the mode setting process for setting the operation mode of each of the air conditioners 9a to 9c is performed at predetermined time intervals, the cooling mode or the heating mode is set for each of the air conditioners 9a to 9c. Thereafter, the set operation mode is not changed while the predetermined time elapses. Therefore, in each of the air conditioners 9a to 9c, the operation mode can be prevented from being frequently changed, and the life of the air conditioners 9a to 9c can be reduced.

(2nd Embodiment)
Next, a ventilation air conditioning system 20 according to a second embodiment, which is another embodiment of the air conditioning system of the present invention, will be described with reference to FIG.

In the ventilating air-conditioning system 20 according to the first embodiment, when it is determined that the period is an intermediate period, the cooling set temperatures of the first AC 9a and the second AC 9b set to the cooling mode are set to the maximum target temperature Tmax, and the heating mode is set. The case where the heating set temperature of the third AC 9c is set to the minimum target temperature Tmin has been described.

On the other hand, when the ventilation air conditioning system 20 according to the second embodiment determines that the period is the middle period, the cooling set temperatures of the first AC 9a and the second AC 9b set to the cooling mode and the third AC 9c set to the heating mode are set. The heating set temperature is set to a temperature based on the average target temperature Tave which is the average value of the individual target temperatures set for each of the living rooms 2a to 2d.

Hereinafter, the ventilation air conditioning system 20 according to the second embodiment will be described focusing on differences from the ventilation air conditioning system 20 according to the first embodiment. The same components as those of the ventilation and air conditioning system 20 according to the first embodiment are denoted by the same reference numerals, and description thereof will be omitted.

FIG. 6 is a flowchart showing a mode determination process executed by the system controller 10 of the ventilation air conditioning system 20 according to the second embodiment as S15 of the mode setting process (see FIG. 3).

This mode determination processing is different from the mode determination processing executed by the system controller 10 according to the first embodiment in that, when it is determined that the process is in the intermediate period by the process of S21 (S21: Yes), S22 and The point is that the processes of S41 to S43 are executed instead of the process of S23.

First, in the process of S41, the system controller 10 calculates an average target temperature Tave which is an average value of the individual target temperatures set in each of the living rooms 2a to 2d. Next, in the process of S42, the system controller 10 sets the operation mode of the first AC 9a and the second AC 9b to the cooling mode, and sets the cooling target temperature during the cooling mode operation to ε degrees (ε is relative to the average target temperature Tave. (A real number greater than or equal to 0). However, the cooling set temperature Tave + ε is a temperature lower than the maximum target temperature Tmax.

In the subsequent process of S43, the system controller 10 sets the operation mode of the third AC 9c to the heating mode, and sets the heating target temperature during the heating mode operation to ζ degrees (ζ is 0 or more) with respect to the average target temperature Tave. (Real number) is set to the temperature. However, the heating set temperature Tave-ζ is a temperature higher than the minimum target temperature Tmin. After the processing of S43, the system controller 10 ends the mode determination processing and returns to the mode setting processing.

The parameters ε and ζ may be values stored in the system controller 10 in advance, or may be configured to be changeable by the user or the installer from the input / output terminal 19.

As described above, in the ventilation and air-conditioning system 20 according to the second embodiment, when it is determined that the period is an intermediate period based on the individual target temperature and the outdoor temperature of each of the living rooms 2a to 2d, the first AC 9a and the second AC 9b operate in the cooling mode. And Tave + ε is set as the cooling set temperature during the cooling mode operation. The third AC 9c is set to the heating mode, and Tave-ζ is set as the heating set temperature during the heating mode operation. In this way, the cooling mode and the cooling set temperature or the heating mode and the heating set temperature are set independently for the plurality of air conditioners 9a to 9c, so that the air conditioning room is not used without the automatic operation of the air conditioners 9a to 9c. 18 can be stably controlled. Therefore, it is possible to provide the ventilation air conditioning system 20 that can perform stable control.

If the temperature of the air conditioning room 18 is higher than the cooling set temperature Tave + ε by the settings of the air conditioners 9a to 9c, the air conditioning room 18 is cooled by the first AC 9a and the second AC 9b so that the temperature of the air conditioning room 18 becomes equal to or lower than the cooling set temperature Tave + ε. You. If the temperature of the air-conditioned room 18 is lower than the heating set temperature Tave-ζ, the third AC 9c heats the air-conditioned room 18 so that the temperature of the air-conditioned room 18 becomes equal to or higher than the heating set temperature Tave-ζ.

Therefore, since the temperature of the air-conditioning room 18 is maintained between the heating set temperature Tave-ζ and the cooling set temperature Tave + ε, the ventilation air-conditioning system 20 sets the temperature of each of the living rooms 2a to 2d at least near the average target temperature Tave in the intermediate period. Temperature. Therefore, the operation of the ventilation and air conditioning system 20 can be predicted, and stable control can be performed.

When the temperature of each of the rooms 2a to 2d becomes close to the average target temperature Tave which is the average value of the individual target temperatures set for each of the rooms 2a to 2d, the individual target set for each of the rooms 2a to 2d is obtained. It is possible to prevent the temperature from greatly deviating from the temperature.

Also, by setting ε and ζ to be positive numbers instead of 0, it is possible to provide a width between the heating set temperature Tave−ζ and the cooling set temperature Tave + ε. The temperature sensors of the air conditioners 9a to 9c have detection errors. As a result, if the heating set temperature and the cooling set temperature are set to the same temperature, the air conditioner set in the heating mode and the air conditioner set in the cooling mode operate simultaneously toward the set temperature, and the energy consumption is reduced. May increase.

On the other hand, by providing a width between the heating set temperature Tave-ζ and the cooling set temperature Tave + ε, the air conditioner set to the heating mode and the air conditioner set to the cooling mode due to a detection error of the temperature sensor are provided. Are suppressed, and energy saving can be achieved.

By setting the parameters ε and ０ to 0, the ventilation air-conditioning system 20 can set the heating set temperature and the cooling set temperature to the same average target temperature Tave. Thus, in the intermediate period, the aim can be adjusted so that the temperatures of the living rooms 2a to 2d become the average target temperature Tave. Therefore, the ventilation air conditioning system 20 can perform more stable control.

In the second embodiment, as in the first embodiment, at least one of the plurality of air conditioners 9a to 9c is set to the cooling mode and the cooling set temperature during the cooling mode operation, and at least one other air conditioner is set. If the heating mode and the heating set temperature at the time of the heating mode operation are set for the table, the same operation and effect as in the second embodiment can be obtained.

Otherwise, the ventilation and air conditioning system 20 according to the second embodiment has the same effect as the ventilation and air conditioning system 20 according to the first embodiment by the same configuration.

(Third embodiment)
Next, with reference to FIGS. 7 and 8, a description will be given of a ventilation air conditioning system 20 according to a third embodiment which is another embodiment of the air conditioning system of the present invention.

In the ventilation and air conditioning system 20 according to the first and second embodiments, when it is determined that the current period is the intermediate period, the cooling set temperatures of the first AC 9a and the second AC 9b set to the cooling mode and the heating of the third AC 9c set to the heating mode are set. The case where the set temperatures are all set to the predetermined fixed temperature has been described.

On the other hand, when the ventilation air-conditioning system 20 according to the third embodiment determines that the current period is the intermediate period, the temperature obtained by the room temperature sensors 11a to 11d for each of the rooms 2a to 2d and the individual target temperature of the room are determined. The absolute value of the difference is calculated, and the set temperature of the air conditioners 9a to 9c is set to a temperature at which the temperature of the room having the largest absolute value can reach the target temperature of the room.

In addition, in the ventilation / air-conditioning system 20 according to the third embodiment, in the interim period, the blower amount of the transfer fan corresponding to the room having the largest absolute value among the transfer fans 3a to 3d is set to “large”. Further, the ventilation air-conditioning system 20 according to the third embodiment sets the air volume of the other transport fans in the interim period based on the individual target temperature and the current temperature of the corresponding living room and the temperature of the air-conditioning room 18. .

Hereinafter, the ventilation air conditioning system 20 according to the third embodiment will be described focusing on differences from the ventilation air conditioning system 20 according to the first embodiment. The same components as those of the ventilation and air conditioning system 20 according to the first embodiment are denoted by the same reference numerals, and description thereof will be omitted.

FIG. 7 is a flowchart showing a mode determination process executed by the system controller 10 of the ventilation and air conditioning system 20 according to the third embodiment as S15 of the mode setting process (see FIG. 3).

This mode determination processing is different from the mode determination processing executed by the system controller 10 according to the first embodiment in that, when it is determined that the process is in the intermediate period by the process of S21 (S21: Yes), S22 and The point is that the processes of S51 to S56 are executed instead of the process of S23.

First, in the process of S51, the system controller 10 sets the first AC 9a and the second AC 9b to the cooling mode, and sets the third AC 9c to the heating mode.

Next, the system controller 10 calculates the absolute value | Tdif | of the difference Tdif between the temperature acquired by the room temperature sensors 11a to 11d and the individual target temperature of the room for each of the rooms 2a to 2d (S52).

Then, the system controller 10 sets the individual target temperature of the living room having the maximum absolute value | Tdif | of the difference between the temperature of each of the living rooms 2a to 2d calculated by the process of S52 and the individual target temperature to the target temperature. It is acquired as Tcal (S53).

Next, the system controller 10 determines whether or not the target temperature Tcal obtained by the processing of S53 is higher than the temperature of the air-conditioned room 18 (S54). In the process of S54, it may be determined whether or not the target temperature Tcal is equal to or higher than the temperature of the air conditioning room 18.

If it is determined that the target temperature Tcal is higher than the temperature of the air conditioning room 18 as a result of the processing in S54 (S54: Yes), the system controller 10 executes the processing in S55.

In the process of S55, the system controller 10 sets, as the heating set temperature of the third AC 9c set in the heating mode, a value obtained by adding η degrees (η is a real number greater than or equal to 0) to the target temperature Tcal. In the process of S55, the system controller 10 sets the maximum target temperature Tmax as the cooling set temperature of the first AC 9a and the second AC 9b set in the cooling mode. After the processing of S55, the system controller 10 ends the mode determination processing and returns to the mode setting processing.

On the other hand, as a result of the processing of S54, when it is determined that the target temperature Tcal is equal to or lower than the temperature of the air conditioning room 18 (S54: No), the system controller 10 executes the processing of S56.

In the process of S56, the system controller 10 sets the cooling temperature set for the first AC 9a and the second AC 9b set to the cooling mode to a value obtained by subtracting θ degrees (θ is a real number equal to or greater than 0) from the target temperature Tcal. In the process of S56, the system controller 10 sets the minimum target temperature Tmin as the heating set temperature of the third AC 9c set in the heating mode. After the processing of S56, the system controller 10 ends the mode determination processing and returns to the mode setting processing.

As described above, in the intermediate period, when the individual target temperature Tcal of the living room where the absolute value | Tdif | of the difference between the temperature of the living room and the individual target temperature is the maximum is higher than the temperature of the air-conditioned room 18, the processing in S55 The heating set temperature of the third AC 9c set in the heating mode is set to be equal to or higher than the individual target temperature Tcal of the living room. Thereby, the temperature of the air-conditioned room 18 is heated by the third AC 9c so as to be equal to or higher than the individual target temperature Tcal of the room where the absolute value | Tdif | Therefore, the ventilation air-conditioning system 20 can control the living room where the absolute value | Tdif | of the difference between the room temperature and the individual target temperature becomes the maximum first as the individual target temperature.

Further, in the intermediate period, when the individual target temperature Tcal of the living room where the absolute value | Tdif | of the difference between the temperature of the living room and the individual target temperature is the maximum is equal to or lower than the temperature of the air-conditioning room 18, the processing in S56 performs the cooling. The cooling set temperatures of the first AC 9a and the second AC 9b set in the mode are set to be equal to or lower than the individual target temperature Tcal of the living room. Thereby, the temperature of the air-conditioning room 18 is cooled by the first AC 9a and the second AC 9b such that the absolute value | Tdif | of the difference becomes equal to or less than the individual target temperature Tcal of the living room. Therefore, the ventilation air-conditioning system 20 can control the living room where the absolute value | Tdif | of the difference between the room temperature and the individual target temperature becomes the maximum first as the individual target temperature.

Therefore, the ventilation and air-conditioning system 20 can control the living room where the temperature of the living room greatly deviates from the individual target temperature in the interim period to become the individual target temperature first.

The mode determination process is one of the mode setting processes executed at predetermined time intervals. In other words, when the temperature of the living room that has greatly deviated from the individual target temperature approaches the individual target temperature, control is performed on the remaining living rooms to bring the room that largely deviates from the individual target temperature closer to the individual target temperature. Done. Therefore, the ventilation air conditioning system 20 can approach the temperature to the individual target temperature in the order of the rooms where the temperature of the living room is different from the individual target temperature.

Accordingly, the ventilation air conditioning system 20 can quickly eliminate the presence of a room whose temperature deviates from the individual target temperature.

In the process of S55, the cooling set temperature of the first AC 9a and the second AC 9b is set to the maximum target temperature Tmax. However, in this case, the temperature of the air-conditioning room 18 is raised to the target temperature Tcal. However, the first AC 9a and the second AC 9b do not operate. Therefore, in the process of S55, the system controller 10 may set the cooling set temperatures of the first AC 9a and the second AC 9b to be equal to or higher than the target temperature Tcal. In this case, the system controller 10 may set the operation of the first AC 9a and the second AC 9b itself to OFF, or set the operation mode of the first AC 9a and the second AC 9b to the heating mode and set the heating set temperature. May be set to the same temperature Tcal + η as the heating set temperature of the third AC 9c.

Similarly, in the process of S56, the heating set temperature of the third AC 9c is set to the minimum target temperature Tmin, but in this case, the temperature of the air-conditioning room 18 is reduced to the target temperature Tcal. 3AC9c does not work. Therefore, in the process of S56, the system controller 10 may set the heating set temperature of the third AC 9c to be equal to or lower than the target temperature Tcal. In this case, the system controller 10 may set the operation of the third AC 9c itself to off, or set the operation mode of the third AC 9c to the cooling mode, and set the cooling set temperature to the first AC 9a and the second AC 9b. May be set to the same temperature Tcal-θ as the cooling set temperature.

Also, in the third embodiment, similarly to the first and second embodiments, at least one of the plurality of air conditioners 9a to 9c is set to the cooling mode and the cooling set temperature during the cooling mode operation. If the heating mode and the heating set temperature during the heating mode operation are set for at least one of the above, the same operation and effect as in the third embodiment can be obtained.

Next, with reference to FIG. 8, a description will be given of an air volume determination process performed by the system controller 10 of the ventilation air conditioning system 20 according to the third embodiment. FIG. 8 is a flowchart showing the air volume determination processing.

The difference between the mode air volume determining process and the air volume determining process executed by the system controller 10 according to the first embodiment is that the mode air volume determining process is performed when the process in S31 determines that the process is in the middle period (S31: Yes). , S32 and S37 are performed instead of S61 and S62.

First, in the processing of S61, the system controller 10 sets the absolute value | Tdif | of the difference between the room temperature and the individual target temperature, which is determined in the processing of S53 of the mode determination processing, to the maximum among the transport fans 3a to 3d. Set the maximum amount of air blown by the transfer fan corresponding to the living room to be used. Here, setting the air volume of the transport fan to the maximum means that the maximum air volume is set among a plurality of levels of air volume that can be set in the transport fan.

As described above, the system controller 10 controls the air-conditioning of the air-conditioning room 18 so that the room in which the absolute value | Tdif | doing. In addition, the system controller 10 sets the blower amount of the transfer fan corresponding to the living room in which the absolute value | Tdif | of the difference between the room temperature and the individual target temperature to be the maximum by the blower amount determining process. I have. Therefore, the ventilation air-conditioning system 20 can control the room in which the temperature of the room greatly differs from the individual target temperature to the individual target temperature earlier in the intermediate period.

In the subsequent process of S62, the system controller 10 sets the air flow rate of the transport fan corresponding to the other living room to the individual target temperature of each of the living rooms 2a to 2d and the current temperature of each of the living rooms 2a to 2d, similarly to S38. , Based on the temperature of the air conditioning room 18. As a result, the air in the air-conditioned room 18 can be appropriately blown to the other rooms, and the air-conditioned room 18 is controlled in accordance with the room in which the absolute value | Tdif | of the difference between the room temperature and the individual target temperature is maximized. With the air, it is possible to suppress the temperature of the living room from deviating from the individual target temperature.

As described above, in the ventilating air-conditioning system 20 according to the third embodiment, when it is determined that the room is in the intermediate period, the absolute value | Tdif | of the difference between the temperature of the living room and the individual target temperature of the living room is maximized. Then, the set temperature of the air conditioners 9a to 9c is set to a temperature that can reach the target temperature of the living room. Thereby, the ventilation and air conditioning system 20 can quickly eliminate the presence of the living room whose temperature deviates from the individual target temperature in the intermediate period.

Otherwise, the ventilation and air conditioning system 20 according to the third embodiment has the same effect as the ventilation and air conditioning system 20 according to the first and second embodiments by the same configuration.

(Fourth embodiment)
Next, a ventilation air conditioning system 20 according to a fourth embodiment, which is another embodiment of the air conditioning system of the present invention, will be described with reference to FIG.

In the ventilation / air-conditioning system 20 according to the first to third embodiments, the description has been given of the setting of the operation mode and the set temperature of each of the air conditioners 9a to 9c when it is determined that the air conditioner is in the intermediate period. On the other hand, the ventilation air-conditioning system 20 according to the fourth embodiment shows an embodiment in which the operation mode and the set temperature of each of the air conditioners 9a to 9c are set when it is determined that the air conditioner is in the cooling period.

Hereinafter, the ventilation air conditioning system 20 according to the fourth embodiment will be described focusing on differences from the ventilation air conditioning system 20 according to the first embodiment. The same components as those of the ventilation and air conditioning system 20 according to the first embodiment are denoted by the same reference numerals, and description thereof will be omitted.

FIG. 9 is a flowchart showing a mode determination process executed by the system controller 10 of the ventilation and air conditioning system 20 according to the fourth embodiment as the process of S15 of the mode setting process (see FIG. 3).

When the mode determination processing is executed, the system controller 10 first determines whether the current outdoor temperature Tout is higher than Tmax + α, which is the first threshold value obtained by adding α degrees (α is a real number equal to or greater than 0) to the maximum target temperature Tmax. A determination is made (S71). The parameter α may be a value stored in the system controller 10 in advance, or may be configured to be changeable from the input / output terminal 19 by a user or an installer.

In the process of S71, instead of determining whether the current outdoor temperature Tout is higher than the first threshold value Tmax + α, it may be determined whether the current outdoor temperature Tout is equal to or higher than the first threshold value Tmax + α.

場合 If the current outdoor temperature Tout is higher than the first threshold value equal to or higher than the maximum target temperature Tmax, it is considered that it is the cooling period for cooling each of the living rooms 2a to 2d. Then, as a result of the processing in S71, when it is determined that the current outdoor temperature Tout is higher than the first threshold value (S71: Yes), the system controller 10 determines that it is in the cooling period, and The process of S72 is executed so that the air conditioning suitable for the cooling period is performed.

Specifically, in the process of S72, the system controller 10 sets the operation mode to the cooling mode in all of the first AC 9a, the second AC 9b, and the third AC 9c. In the same process, the system controller 10 sets the air conditioners 9a to 9c to a temperature obtained by subtracting ι degrees (ι is a real number of 0 or more) from the minimum target temperature Tmin as the cooling set temperature during the cooling mode operation. Set. The parameter ι may be a value stored in the system controller 10 in advance, or may be configured to be changeable from the input / output terminal 19 by a user or an installer.

Accordingly, when the air-conditioning system 20 is in the cooling period, the temperature of the air-conditioning room 18 is set to the minimum target temperature Tmin of the individual target temperature set for each of the living rooms 2a to 2d by operating all of the air conditioners 9a to 9c. Control is performed as follows. Therefore, the ventilation air conditioning system 20 can make each of the living rooms 2a to 2d surely approach the individual target temperature. The ventilation air conditioning system 20 can stably control the air conditioning of the air conditioning room 18 without using the automatic operation of each of the air conditioners 9a to 9c. Further, in this case, since the plurality of air conditioners 9a to 9c provided in the air conditioning room 18 are all set to the same operation mode and the same set temperature, even if one of them fails, the air conditioning of the air conditioning room 18 is continued. You can do it. Therefore, it is possible to provide the ventilation air conditioning system 20 that can perform stable control.

On the other hand, when it is determined that the current outdoor temperature Tout is equal to or less than the first threshold as a result of the process of S71 (S71: No), the system controller 10 is executed by the system controller 10 according to the first embodiment. The same process as S24 of the mode determination process (see FIG. 4) is executed. Thereby, the ventilation air conditioning system 20 can stably control the air conditioning of the air conditioning room 18 without using the automatic operation of each of the air conditioners 9a to 9c. Therefore, it is possible to provide the ventilation air conditioning system 20 that can perform stable control.

As described above, in the ventilation air conditioning system 20 according to the fourth embodiment, when it is determined that the air conditioner is in the cooling period, the cooling mode is set for all the air conditioners 9a to 9c provided in the air conditioning room 18, and the cooling set temperature is set. Is set to be equal to or lower than the minimum target temperature Tmin, so that the temperatures of the living rooms 2a to 2d can be stably controlled.

(Fifth embodiment)
Next, a ventilation air conditioning system 20 according to a fifth embodiment, which is another embodiment of the air conditioning system of the present invention, will be described with reference to FIG. The ventilation air-conditioning system 20 according to the fifth embodiment shows an embodiment of the setting of the operation mode and the set temperature of each of the air conditioners 9a to 9c when it is determined that the heating period is set.

Hereinafter, the ventilation air conditioning system 20 according to the fifth embodiment will be described focusing on differences from the ventilation air conditioning system 20 according to the first embodiment. The same components as those of the ventilation and air conditioning system 20 according to the first embodiment are denoted by the same reference numerals, and description thereof will be omitted.

FIG. 10 is a flowchart showing a mode determination process executed by the system controller 10 of the ventilation and air conditioning system 20 according to the fifth embodiment as S15 of the mode setting process (see FIG. 3).

When the system controller 10 executes this mode determination processing, first, the current outdoor temperature Tout is lower than Tmin-β which is a second threshold value obtained by subtracting β degrees (β is a real number equal to or more than 0) from the minimum target temperature Tmin. Is determined (S81). The parameter β may be a value stored in the system controller 10 in advance, or may be configured to be changeable from the input / output terminal 19 by a user or an installer.

In the process of S81, instead of determining whether the current outdoor temperature Tout is lower than the second threshold value Tmin-β, it may be determined whether the current outdoor temperature Tout is equal to or lower than the second threshold value Tmin-β.

場合 If the current outdoor temperature Tout is lower than the second threshold value equal to or lower than the minimum target temperature Tmin, it is considered that the heating period is for heating each of the living rooms 2a to 2d. Therefore, as a result of the processing in S81, when it is determined that the current outdoor temperature Tout is lower than the second threshold value (S81: Yes), the system controller 10 determines that the heating period is in progress, and the air conditioning room 18 The processing of S82 is performed so that air conditioning suitable for the heating period is performed.

Specifically, in the process of S82, the system controller 10 sets the operation mode to the heating mode in all of the first AC 9a, the second AC 9b, and the third AC 9c. In the same process, the system controller 10 applies a temperature obtained by adding κ degrees (κ is a real number of 0 or more) to the maximum target temperature Tmax as a heating set temperature at the time of the heating mode operation for these air conditioners 9a to 9c. Set to. The parameter κ may be a value stored in the system controller 10 in advance, or may be configured to be changeable from the input / output terminal 19 by a user or an installer.

Accordingly, when the air-conditioning system 20 is in the heating period, the temperature of the air-conditioning room 18 is set to the maximum target temperature Tmax of the individual target temperature set for each of the living rooms 2a to 2d by operating all the air conditioners 9a to 9c. Control is performed as follows. Therefore, the ventilation air conditioning system 20 can make each of the living rooms 2a to 2d surely approach the individual target temperature. The ventilation air conditioning system 20 can stably control the air conditioning of the air conditioning room 18 without using the automatic operation of each of the air conditioners 9a to 9c. Further, in this case, since the plurality of air conditioners 9a to 9c provided in the air conditioning room 18 are all set to the same operation mode and the same set temperature, even if one of them fails, the air conditioning of the air conditioning room 18 is continued. You can do it. Therefore, it is possible to provide the ventilation air conditioning system 20 that can perform stable control.

On the other hand, when it is determined that the current outdoor temperature Tout is equal to or higher than the second threshold as a result of the processing in S81 (S81: No), the system controller 10 is executed by the system controller 10 according to the first embodiment. The same process as S24 of the mode determination process (see FIG. 4) is executed. Thereby, the ventilation air conditioning system 20 can stably control the air conditioning of the air conditioning room 18 without using the automatic operation of each of the air conditioners 9a to 9c. Therefore, it is possible to provide the ventilation air conditioning system 20 that can perform stable control.

As described above, in the ventilation air conditioning system 20 according to the fifth embodiment, when it is determined that the heating period is set, the heating mode is set for all the air conditioners 9a to 9c provided in the air conditioning room 18, and the heating set temperature is set. Is set to be equal to or lower than the maximum target temperature Tmax, so that the temperatures of the living rooms 2a to 2d can be stably controlled.

(Sixth embodiment)
Next, a ventilation air conditioning system 20 according to a sixth embodiment, which is another embodiment of the air conditioning system of the present invention, will be described with reference to FIG. The ventilation air-conditioning system 20 according to the sixth embodiment shows an embodiment in which the operation modes and the set temperatures of the air conditioners 9a to 9c are set.

Normally, the air conditioners 9a to 9c have a dehumidifying function when operating in the cooling mode. In summer, for example, the air conditioners 9a to 9c operate in the cooling mode. As a result, the air conditioning room is dehumidified and maintained at an appropriate humidity. However, in Japan, for example, during the period from May to June, which corresponds to the middle period, the temperature is about 20 to 26 degrees, but the humidity rises to about 75% because it corresponds to the rainy season. That is, the temperature is in a comfortable range, but the comfort is impaired by the humidity.

Therefore, in the present embodiment, a dehumidification process using a plurality of air conditioners 9a to 9c will be described.

The configuration in the present embodiment is the same as the configuration in the first embodiment, except that an air-conditioning-room humidity sensor 15 is connected to the air-volume determining unit 31, and the air-volume determining unit 31 obtains the humidity of the air-conditioning room. It is possible. That is, in addition to the configuration shown in FIG. 2, the air-conditioning-room humidity sensor 15 is connected to the air-blowing amount determination unit 31.

Hereinafter, a description will be given of the processing performed by the air volume determining unit 31 and the mode setting unit 32 in the above configuration. Note that the system controller 10 configures the mode setting unit 32 by executing the mode determination processing shown in FIG.

When the system controller 10 executes the mode determination processing (S15) shown in FIG. 11, first, it is determined whether or not it has been determined in the mode determination processing (see FIG. 4) that the processing is in the interim period (S21). As a result, when it is determined that the period is the intermediate period (S21: Yes), the system controller 10 then determines whether the humidity of the air in the air conditioning room 18 is higher than a set target humidity (air conditioning room target humidity). Is determined (S91). The air conditioning room target humidity is the humidity input from the input / output terminal 19, that is, the target humidity input receiving unit.

Here, when the humidity of the air in the air conditioning room 18 is higher than the set air conditioning room target humidity, the system controller 10 dehumidifies the air in the air conditioning room 18 so that the humidity becomes the air conditioning room target humidity (S91). : YES).

湿 The dehumidification of the air-conditioning room 18 in the present embodiment is performed as follows. That is, the mode setting unit configuring the system controller 10 sets the first AC to the cooling mode, and sets the cooling set temperature in the cooling mode to the dehumidifying temperature in the air conditioning room 18 (S92). Specifically, the system controller 10 calculates the dew point temperature of the air conditioning room based on the temperature of the air conditioning room acquired from the air conditioning room temperature sensor 14 and the humidity of the air conditioning room acquired from the air conditioning room humidity sensor 15. Then, the cooling set temperature of the first AC is set to be equal to or lower than the calculated dew point temperature. Further, the cooling setting temperature is changed based on the magnitude of the difference between the humidity of the air in the air conditioning room 18 and the target humidity of the air conditioning room. Specifically, the larger the deviation, the lower the cooling set temperature, that is, the larger the difference between the cooling set temperature and the dew point temperature.

The mode setting unit included in the system controller 10 sets the third AC to the heating mode, and sets the heating set temperature in the heating mode to a temperature at which the cooling of the air conditioning room 18 by the first AC is offset (S93). In other words, the offset temperature can be said to be a temperature at which the temperature before the dehumidifying process is performed on the air-conditioned room 18 can be maintained. Specifically, for example, it is assumed that the temperature of the air conditioning room 18 is 22 degrees, and the cooling setting temperature is 18 degrees. In this case, since the temperature difference is 4 degrees, the heating setting temperature is set to 26 degrees, which is 4 degrees higher than the 22 degrees which is the temperature of the air conditioning room 18. Thus, the cooling by the first AC can be offset by the heating by the third AC.

However, it is conceivable that this offset differs depending on the size of the air conditioning room 18, the heat insulation state, and the amount of outside air introduced. Therefore, the mode setting unit included in the system controller 10 may store the temperature before performing the dehumidifying process and dynamically change the heating setting temperature of the third AC so that the temperature can be maintained.

By the above processing, even in the middle period, where the temperature of the living room does not need to be controlled, when the humidity is high, the dehumidification can be performed efficiently, and the natural temperature environment suitable for the season and the more comfortable It is possible to simultaneously provide a high humidity environment.

In addition, in the present embodiment, piping required for operating the dehumidifier is not required, and the ventilation and air conditioning system 20 having a higher dehumidification capacity can be provided.

In the present embodiment, the determination of the interim period is performed, and the implementation in the interim period has been described as an example. However, the determination of the interim period based on the description in the first embodiment is not necessarily required. That is, the above-described dehumidification process may be performed only by judging the temperature and the humidity without performing the determination of the interim period.

湿度 Also, it is difficult to stabilize the humidity to a constant value. For this reason, the target air conditioning room humidity input via the input / output terminal 19 may be set as a predetermined humidity range. Specifically, the target air-conditioning room humidity is set in a range of 45% to 55%. In this case, if the air conditioning room target humidity is within this range, the dehumidification process is not performed. If the air conditioning room target humidity exceeds the upper limit of 55%, the air conditioning room target humidity is set to the average value (50%) of this range. carry out. This makes it easy to control humidity, which is difficult to control, and avoids frequent on / off of the plurality of air conditioners 9a to 9c.

As described above, the present invention has been described based on the embodiments. However, the present invention is not limited to the above-described embodiments, and various improvements and modifications can be easily made without departing from the gist of the present invention. It can be inferred. For example, in each embodiment, a part or a plurality of parts of the configuration of another embodiment is added to the embodiment or replaced with a part or a plurality of parts of the configuration of the embodiment, and the like. The embodiment may be modified to be configured. The numerical values given in the above embodiments are merely examples, and other numerical values can be naturally used.

In each of the above embodiments, the system controller 10 is provided independently of the outside air introduction fan 4 and each of the exhaust fans 5a to 5d, and the system controller 10 serves as a hub, and the system controller 10 and the outside air introduction fan 4, and the system controller 10 and each The case where communication is performed between the exhaust fans 5a to 5d has been described. On the other hand, the outside air introduction fan 4 and the exhaust fans 5a to 5d may directly communicate with each other, and control may be performed in conjunction with each other. In this case, the system controller 10 may be built in the outside air introduction fan 4.

The circulation fans 6a to 6d and the transport fans 3a to 3d are connected to each other by a duct connecting the living rooms 2a to 2d and the air conditioning room 18. However, the circulation fans 6a to 6d do not necessarily need to be connected by a duct, and a space such as a corridor connecting the living rooms 2a to 2d can be regarded as a duct. In this case, the air in the rooms 2a to 2d is conveyed from the rooms 2a to 2d to the corridor by the circulation fan. The air in the living rooms 2a to 2d conveyed to the corridor is taken into the air conditioning room 18 communicating with the corridor. The intake into the air-conditioning room 18 is performed by providing an intake fan on the wall facing the corridor of the air-conditioning room, or by introducing a negative pressure into the air-conditioning room 18 without using the circulation fan and / or the intake fan. May be. Even with such a configuration, it is expected that the circulation efficiency is reduced as compared with the case where the connection is made by the duct, but it can contribute to uniformity of the humidity.

換 気 The ventilation and air-conditioning system according to the present invention is applicable to complex houses such as detached houses and condominiums. When applied to a complex house, one system corresponds to a household unit, and each household is not a single living room.

DESCRIPTION OF SYMBOLS 1 General house 2a Living room 2b Living room 2c Living room 2d Living room 3a Transport fan 3b Transport fan 3c Transport fan 3d Transport fan 4 Outside air introduction fan 5a Exhaust fan 5b Exhaust fan 5c Exhaust fan 5d Exhaust fan 6a Circulating fan 6b Circulating fan 6d Circulating fan 6d Circulating fan Fan 7 Outdoor temperature sensor 9a 1st air conditioner (1st AC)
9b 2nd air conditioner (2nd AC)
9c 3rd air conditioner (3rd AC)
10 System Controller 11a Living Room Temperature Sensor 11b Living Room Temperature Sensor 11c Living Room Temperature Sensor 11d Living Room Temperature Sensor 12a Living Room Humidity Sensor 12b Living Room Humidity Sensor 12c Living Room Humidity Sensor 12d Living Room Humidity Sensor 14 Air Conditioning Room Temperature Sensor 15 Air Conditioning Room Humidity Sensor 16 Humidifier 17 Dehumidifying 18 Air-conditioning room 19 Input / output terminal 20 Ventilation air-conditioning system 31 Ventilation amount determination unit 32 Mode setting unit 33 Fan air volume control unit

Claims (19)

1. A plurality of independently controllable air conditioners provided in the air conditioning room;
   A plurality of transfer fans provided for each of the plurality of living rooms, for transferring the air in the air conditioning room to a plurality of living rooms different from the air conditioning room,
   A room temperature sensor for acquiring the temperature of each of the plurality of rooms,
   An outdoor temperature sensor that acquires the outdoor temperature,
   An air conditioning room temperature sensor for acquiring the temperature of the air conditioning room,
   A target temperature input receiving unit that receives an input of an individual target temperature that is a target temperature of each of the plurality of living rooms;
   A system controller that controls the air conditioner and the transfer fan,
   The system controller comprises:
   Based on the individual target temperature acquired from the target temperature input receiving unit, the temperature of each of the plurality of living rooms acquired by the living room temperature sensor, and the temperature of the air conditioning room acquired by the air conditioning room temperature sensor, An air volume determining unit for determining the air volume,
   Based on the individual target temperature obtained from the target temperature input receiving unit and the outdoor temperature obtained by the outdoor temperature sensor, a cooling mode for each of the plurality of independent air conditioners and a cooling setting during the cooling mode operation. A mode setting unit that sets a temperature or a heating set temperature during the heating mode and the heating mode operation,
   A fan air volume control unit that independently blows the air in the air-conditioned room air-conditioned based on the setting by the mode setting unit to the living room with the air flow amount of the transport fan determined by the air flow amount determination unit. Equipped air conditioning system.
2. The mode setting unit includes:
   The lowest temperature among the plurality of individual target temperatures is the lowest target temperature, the highest temperature is the highest target temperature, and the outdoor temperature is set to be lower than the first target threshold which is lower than or equal to the highest target temperature. 2. If the second threshold is higher than the second threshold, the heating mode is set in at least one of the plurality of air conditioners and the cooling mode is set in at least one of the plurality of air conditioners. Air conditioning system.
3. The mode setting unit, when it is determined that the intermediate period,
   The set temperature of the air conditioner in which the heating mode has been set is equal to or lower than the minimum target temperature,
   The air conditioning system according to claim 2, wherein a set temperature of the air conditioner in which the cooling mode is set is equal to or higher than the maximum target temperature.
4. The mode setting unit, when it is determined that the intermediate period,
   The set temperature of the air conditioner in which the heating mode is set is set to a temperature that is greater than the minimum target temperature and equal to or less than the average value of the plurality of individual target temperatures,
   The air conditioning system according to claim 2, wherein a set temperature of the air conditioner in which the cooling mode is set is set to a temperature lower than the maximum target temperature and equal to or higher than the average value.
5. 5. The air conditioning system according to claim 4, wherein the mode setting unit sets the average temperature of the air conditioner set to the heating mode and the air conditioner set to the cooling mode when the intermediate period is determined.
6. The mode setting unit, when it is determined that the intermediate period,
   The absolute value of the difference between the temperature acquired by the living room temperature sensor and the target temperature of the living room is calculated for each living room, and the temperature of the living room with the largest absolute value is set to a temperature that can reach the target temperature of the living room. The air conditioning system according to claim 2, wherein a set temperature of the air conditioner is set.
7. The mode setting unit includes:
   If the target temperature of the room with the largest absolute value is higher than the temperature of the air conditioning room, set the set temperature to the target temperature or higher for the air conditioner set to the heating mode,
   7. The air conditioner according to claim 6, wherein when the target temperature of the room having the largest absolute value is lower than the temperature of the air conditioning room, a set temperature of the air conditioner set to the cooling mode is set to be equal to or lower than the target temperature. Air conditioning system.
8. The mode setting unit includes:
   The highest temperature among the plurality of individual target temperatures is the highest target temperature, and when the outdoor temperature is higher than a first threshold value set to be equal to or higher than the highest target temperature, it is determined to be in the cooling period and at least the plurality of air conditioners are determined. The air conditioning system according to claim 1, wherein the cooling mode is set.
9. The mode setting unit includes:
   The air conditioning system according to claim 8, wherein the cooling mode is set, and a cooling set temperature during the cooling mode operation is set to a temperature equal to or lower than a lowest target temperature which is the lowest temperature among the plurality of individual target temperatures.
10. The mode setting unit includes:
    When the lowest temperature among the plurality of individual target temperatures is the lowest target temperature, and when the outdoor temperature is lower than the second threshold value set to be equal to or lower than the lowest target temperature, it is determined to be in the heating period and at least a plurality of air conditioners are determined. The air conditioning system according to claim 1, wherein the heating mode is set.
11. The mode setting unit includes:
    The air conditioning system according to claim 10, wherein the heating mode is set, and a heating set temperature during the heating mode operation is set to a temperature equal to or higher than a highest target temperature that is the highest temperature among the plurality of individual target temperatures.
12. The mode setting unit includes:
    The air conditioning system according to any one of claims 1 to 11, wherein the set operation mode is not changed for a predetermined time after the cooling mode or the heating mode is set in the air conditioner.
13. The mode setting unit includes:
    The air conditioning system according to claim 2, wherein the determination of the intermediate period is performed within a range of 4 hours before and after the mid-sun time of the sun.
14. An outside air introduction fan for introducing outside air into the air conditioning room,
    The mode setting unit includes:
    If it is determined that the intermediate period, and the outdoor temperature is within the range of the maximum target temperature from the minimum target temperature, the outdoor temperature is higher than the maximum target temperature or lower than the minimum target temperature. The air conditioning system according to claim 2, wherein the amount of outside air introduced into the air conditioning room by the outside air introduction fan is increased as compared with a case where the temperature is low.
15. An air conditioning room humidity sensor for acquiring the humidity of the air conditioning room,
    A target humidity input receiving unit that receives an input of a target humidity of the living room,
    The system controller comprises:
    If the humidity of the air conditioning room acquired by the air conditioning room humidity sensor is higher than the target humidity acquired from the target humidity input reception unit, it is determined to be an intermediate period,
    A cooling mode for at least one of the plurality of independent air conditioners, and a cooling set temperature during the cooling mode operation, the temperature of the air conditioning room acquired by the air conditioning room temperature sensor and the air conditioning room humidity sensor acquired. Based on the humidity of the air-conditioned room that was set to a temperature that can dehumidify the air in the air-conditioned room,
    The air conditioning system according to claim 1, wherein a heating mode and a heating set temperature during the heating mode operation are set for at least one other air conditioner other than the air conditioner set to the cooling mode.
16. A plurality of independently controllable air conditioners provided in the air conditioning room;
    A transfer fan that transfers the air in the air conditioning room to a plurality of living rooms different from the air conditioning room,
    An air conditioning room temperature sensor for acquiring the temperature of the air conditioning room,
    An air conditioning room humidity sensor for acquiring the humidity of the air conditioning room,
    A target humidity input receiving unit that receives an input of a target humidity of the living room,
    A system controller that controls the air conditioner,
    The system controller comprises:
    When the humidity of the air conditioning room acquired by the air conditioning room humidity sensor is higher than the target humidity acquired from the target humidity input reception unit,
    A cooling mode for at least one of the plurality of independent air conditioners, and a cooling set temperature during the cooling mode operation, the temperature of the air conditioning room acquired by the air conditioning room temperature sensor and the air conditioning room humidity sensor acquired. Based on the humidity of the air-conditioned room that was set to a temperature that can dehumidify the air in the air-conditioned room,
    An air conditioning system comprising a mode setting unit that sets a heating mode and a heating set temperature during the heating mode operation for at least one other air conditioner other than the air conditioner set to the cooling mode.
17. A target temperature input receiving unit that receives an input of a target temperature of the living room,
    An air conditioning room temperature sensor for acquiring the temperature of the air conditioning room,
    The system controller comprises:
    17. The heating set temperature for maintaining the temperature of the air-conditioned room at a target temperature of the living room by heating by the air conditioner set to the heating mode with respect to cooling by the air conditioner set to the cooling mode. Air conditioning system.
18. The system controller comprises:
    The air conditioning system according to claim 16, wherein the cooling set temperature of the air conditioner operating in the cooling mode is set based on a difference between the target humidity and the humidity of the air conditioning room.
19. 17. The air conditioning system according to claim 16, wherein the target humidity input receiving unit receives the target humidity as a predetermined humidity range.

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