JP7523397B2 - Air Conditioning System - Google Patents

Description

The technology disclosed in this specification relates to air conditioning systems.

Patent document 1 discloses an air conditioning system. The air conditioning system in Patent document 1 includes a temperature sensor that detects the outdoor temperature, an air conditioning device that conditions the indoor air, and a control unit that controls the air conditioning device.

JP 2020-134097 A

In a temperature sensor that detects the outdoor temperature, the detected temperature may become higher or lower in the short term due to the influence of the surrounding environment. For example, the detected temperature may become higher in the short term due to the influence of solar radiation, or may become lower in the short term due to the influence of radiative cooling. In this case, if the output of the air conditioner is controlled based on the temperature detected by the temperature sensor, the output of the air conditioner may become higher or lower in the short term. As a result, for example, the operation of the thermal valve of the air conditioner may become larger in the short term, which may increase the load on the parts of the air conditioner (e.g., the thermal valve). Therefore, this specification provides a technology that can reduce the load on the parts of the air conditioner.

The air conditioning system disclosed in this specification includes a temperature sensor that detects an outdoor temperature, an air conditioning device that performs indoor air conditioning at an air conditioning set temperature according to the temperature detected by the temperature sensor, and a control unit that controls the air conditioning device. The control unit is configured to determine a calculation reference value (Tg) based on a short-term average value (Tg1) that is an average value of the temperature detected by the temperature sensor in a first period and a long-term average value (Tg2) that is an average value of the temperature detected by the temperature sensor in a second period longer than the first period, and to calculate the air conditioning set temperature of the air conditioning device based on the calculation reference value (Tg). When the absolute value of the difference between the short-term average value (Tg1) and the long-term average value (Tg2) exceeds a predetermined threshold, the control unit determines the calculation reference value (Tg) to be the lower of the short-term average value (Tg1) and the long-term average value (Tg2) plus a correction value that is equal to or less than the threshold, or determines the calculation reference value (Tg) to be the higher of the short-term average value (Tg1) and the long-term average value (Tg2) minus a correction value that is equal to or less than the threshold.

In a temperature sensor that detects outdoor temperatures, the detected temperature may become high or low in the short term due to the influence of the surrounding environment. However, according to the above configuration, by determining the calculation reference value (Tg) using a correction value according to the difference between the short-term average value (Tg1) and the long-term average value (Tg2) of the detected temperature of the temperature sensor, it is possible to determine a calculation reference value (Tg) that reflects both the short-term and long-term temperature trends even when the difference between the short-term average value (Tg1) and the long-term average value (Tg2) is large. Then, by calculating the air conditioning set temperature of the air conditioner based on the calculation reference value (Tg) determined using the correction value, it is possible to prevent the air conditioning set temperature from becoming extremely high or low in the short term, even if the detected temperature of the temperature sensor may become high or low in the short term. This reduces the load on the parts of the air conditioner (e.g., thermal valves).

The control unit may determine the short-term average value (Tg1) as the calculation reference value (Tg) if the absolute value of the difference between the short-term average value (Tg1) and the long-term average value (Tg2) does not exceed the threshold value.

According to this configuration, when the difference between the short-term average value (Tg1) and the long-term average value (Tg2) is small, the short-term average value (Tg1) is determined as the calculation reference value (Tg), so that the air conditioning setting temperature can be calculated based on a temperature close to the current outdoor temperature.

The control unit may be configured to calculate the air conditioning setting temperature of the air conditioning device based on a calculation formula corresponding to the capacity of the air conditioning device and the calculation reference value (Tg).

With this configuration, the air conditioning set temperature can be calculated based on the capacity of the air conditioning device. Therefore, air conditioning can be performed at an appropriate air conditioning set temperature.

1 is a block diagram showing a configuration of an air conditioning system 2 according to an embodiment. 1 is a diagram illustrating a schematic configuration of a heat source unit 100 according to an embodiment. 1 is a flowchart of a Tg determination process according to an embodiment. 4 is a flowchart of a heating temperature setting calculation process according to the embodiment.

The air conditioning system 2 according to the embodiment will be described with reference to the drawings. As shown in FIG. 1, the air conditioning system 2 includes a heat source unit 100, a heating radiator 90 (a first heating radiator 90a and a second heating radiator 90b), and a remote control 200. The air conditioning system 2 is, for example, a floor heating system or a room heating system. The air conditioning system 2 is a system that supplies a heating medium (for example, water) heated by the heat source unit 100 to the heating radiator 90, and heats the room (for example, a room, a kitchen, a dressing room, etc.) by dissipating the heat of the heating medium by the heating radiator 90. The heating radiator 90 is installed indoors (for example, a room, a kitchen, a dressing room, etc.). The heat source unit 100 is, for example, an electric, gas, or electric and gas heat source unit. The heating radiator 90 is, for example, a floor heater, a fan coil unit, a panel radiator, etc. The remote control 200 is, for example, a remote control for a floor heating system, a remote control for a room heating system, etc.

(Configuration of heat source unit 100)
The configuration of the heat source machine 100 will be described. The configuration of the electric and gas type heat source machine 100 will be described below. The heat source machine 100 is a device that heats water for heating (heat medium for heating) to generate hot water and supplies the generated hot water to the heating radiator 90. The heat source machine 100 includes an operation unit 102, a communication I/F 104, a temperature sensor 105, a control unit 106, and a heating unit 108.

(Configuration of heating unit 108; FIG. 2)
The configuration of the heating section 108 will be described. As shown in FIG. 2, the heating section 108 includes a heat exchange unit 7, a heat pump heat source 4, and a combustion heat source 3. The heat exchange unit 7 includes a heat exchanger 70. The heat exchanger 70 is, for example, a plate-type heat exchanger, and can heat water (heating heat medium) passing through the plate by heat exchange between a heating heat medium and a heating heat medium. The upstream end of the heating outgoing path 52 and the upstream end of the heat medium outgoing path 62 are connected to the heat exchanger 70. The water (heating heat medium) heated by the heat exchanger 70 is sent to the heating outgoing path 52. The heating heat medium heat-exchanged by the heat exchanger 70 is sent to the heat medium outgoing path 62.

The heating outflow path 52 is provided with a heating outlet hot water thermistor 46. The heating outlet hot water thermistor 46 detects the temperature of the water flowing through the heating outflow path 52. The downstream end of the heating outflow path 52 is connected to the upstream end of the first heating path 41, the upstream end of the second heating path 42, and the upstream end of the anti-freeze bypass path 56.

The first heating path 41 is a path that supplies hot water (heat medium for heating) from the heating unit 108 to the first heating radiator 90a. The first heating path 41 is configured to return from the heating unit 108 to the heating unit 108 again via the first heating radiator 90a. The heat of the hot water is radiated from the first heating radiator 90a to heat the room. The first heating radiator 90a is, for example, a panel radiator or a floor heater for heating a room.

The second heating path 42 is a path that supplies hot water (heat medium for heating) from the heating unit 108 to the second heating radiator 90b. The second heating path 42 is configured to return from the heating unit 108 to the heating unit 108 again via the second heating radiator 90b. The heat of the hot water is radiated from the second heating radiator 90b to heat the room. The second heating radiator 90b is, for example, a fan coil unit for heating a room.

The downstream end of the first heating path 41, the downstream end of the second heating path 42, and the downstream end of the antifreeze bypass path 56 are connected to the upstream end of the heat pump forward path 53. A heat pump water inlet thermistor 82 is provided in the heat pump forward path 53. The heat pump water inlet thermistor 82 detects the temperature of the water flowing through the heat pump forward path 53.

The heat pump heat source 4 heats the water flowing in from the downstream end of the heat pump forward path 53 and sends it to the upstream end of the heat pump return path 51. The heat pump heat source 4 is equipped with a refrigerant circulation path 18 for circulating a refrigerant (for example, an HFC refrigerant such as R32 or a CO2 refrigerant such as R744), a compressor 20, a condenser 22, a pressure reduction mechanism 24, an evaporator 26, and a fan 28. The compressor 20 pressurizes the refrigerant in a gas phase and sends it to the condenser 22. The condenser 22 condenses the refrigerant by releasing heat to water (heat medium for heating) and sends the refrigerant in a liquid phase to the pressure reduction mechanism 24. The pressure reduction mechanism 24 is, for example, an expansion valve whose opening degree can be adjusted, and reduces the pressure of the refrigerant and sends it to the evaporator 26. The evaporator 26 evaporates the refrigerant by absorbing heat from the outside air blown by the fan 28, and sends the refrigerant in a gas phase to the compressor 20. In the heat pump heat source 4, the water (heat medium) sent from the heat pump forward path 53 is heated in the condenser 22, and the heated hot water is sent from the condenser 22 to the heat pump return path 51.

The heat pump return path 51 is provided with a first circulation pump 50 and a heat pump outlet thermistor 81. When the first circulation pump 50 is driven, water (heat medium for heating) circulates between the heating section 108 and the heating radiator 90 (90a, 90b). The heat pump outlet thermistor 81 detects the temperature of the water flowing through the heat pump return path 51.

A three-way valve 55 is provided at the downstream end of the heat pump return path 51. The three-way valve 55 is connected to the upstream end of the heating return path 57 and the upstream end of the heating bypass path 54. The three-way valve 55 can adjust the ratio of the flow rate of water flowing from the heat pump return path 51 to the heating return path 57 and the flow rate of water flowing from the heat pump return path 51 to the heating bypass path 54. The downstream end of the heating return path 57 is connected to the heat exchanger 70. The downstream end of the heating bypass path 54 is connected to the heating outbound path 52.

The combustion heat source 3 includes a burner 31 and a heat exchanger 32. The burner 31 burns fuel such as city gas. The downstream end of the heat medium forward path 62 and the upstream end of the heat medium return path 61 are connected to the heat exchanger 32. The heat exchanger 32 heats the heating medium flowing in from the downstream end of the heat medium forward path 62 with the combustion heat of the burner 31, and sends the heated heating medium to the upstream end of the heat medium return path 61. The downstream end of the heat medium return path 61 is connected to the heat exchanger 70.

The heat transfer medium inlet path 62 is provided with a thermal valve 71 and a second circulation pump 60. The thermal valve 71 opens and closes the heat transfer medium inlet path 62. When the second circulation pump 60 is driven, the heat transfer medium for heating circulates between the heat exchanger 70 and the combustion heat source 3.

Next, the configuration of the heat source unit 100 other than the heating unit 108 will be described. The operation unit 102 of the heat source unit 100 shown in FIG. 1 has multiple buttons and switches (not shown). A user or installer of the air conditioning system 2 can input various instructions to the heat source unit 100 by operating the operation unit 102. The communication I/F 104 is an interface for performing wired or wireless communication with the remote control 200.

The temperature sensor 105 is attached, for example, to the housing of the heat pump heat source 4 of the heat source device 100 (see FIG. 2). The temperature sensor 105 is capable of detecting the outdoor temperature (outdoor air temperature) where the heat pump heat source 4 is installed. Information on the detected temperature Ts of the temperature sensor 105 is supplied to the control unit 106 at a predetermined time interval (for example, every 10 minutes).

The control unit 106 is equipped with a memory unit 107 composed of a volatile memory, a non-volatile memory, etc., and controls the operation of each part of the heat source unit 100 according to the program stored in the memory unit 107.

The control unit 106 also stores information on the detected temperature Ts obtained from the temperature sensor 105 at a predetermined time interval (for example, 10-minute intervals) in the memory unit 107. Furthermore, the control unit 106 calculates the average value of the past outside air temperature based on the information on the detected temperature Ts obtained from the temperature sensor 105. For example, the control unit 106 calculates the average value of the outside air temperature (detected temperature Ts of the temperature sensor 105) for the last two hours (from two hours before the current time to the current time) and stores the value in the memory unit 107 as a short-term average value Tg1. The control unit 106 also calculates the average value of the outside air temperature (detected temperature Ts of the temperature sensor 105) for the last seven days (from the current time seven days before today to the current time today) and stores the value in the memory unit 107 as a long-term average value Tg2. The control unit 106 also determines the calculation reference value Tg for calculating the heating setting temperature Y based on the relationship between the short-term average value Tg1 and the long-term average value Tg2. The process for determining the calculation reference value Tg and the process for calculating the heating setting temperature Y will be described later.

The storage unit 107 stores heating-related information 110 in advance. The heating-related information 110 is used in the process of calculating the heating setting temperature Y of the air conditioning system 2. The heating-related information 110 includes information on a plurality of conditions A1 to D1 and a plurality of calculation formulas a1 to d1. Each of the conditions A1 to D1 is determined, for example, by the heat loss coefficient of the house and the heat transfer coefficient (also called the heat radiation coefficient) of the heating radiator 90 (the first heating radiator 90a and the second heating radiator 90b). For example, the condition A1 is a case where the heat loss coefficient of the house is 1.6 W/m ² ·°C, and the heat transfer coefficient of the heating radiator 90 is 1.6 W/m ² ·°C. Furthermore, the condition B1 is a case where the heat loss coefficient of the house is 1.4 W/m ² ·°C, and the heat transfer coefficient of the heating radiator 90 is 1.6 W/m ² ·°C. In the air conditioning system 2, the installer of the air conditioning system 2 can operate the operation unit 102 of the heat source unit 100 to select a specific condition (for example, condition A1) from a plurality of conditions A1 to D1 and input the selected condition to the heat source unit 100.

Each of the calculation formulas a1 to d1 of the heating-related information 110 is a formula for calculating the heating reference temperature X in the heating radiator 90 based on a calculation reference value Tg described below. The multiple calculation formulas a1 to d1 are preset to correspond to multiple conditions A1 to D1, respectively. For example, the calculation formula a1 corresponding to condition A1 is heating reference temperature X = -0.9 x Tg (calculation reference value) + 50. Also, the calculation formula b1 corresponding to condition B1 is heating reference temperature X1 = -0.75 x Tg (calculation reference value) + 45. The conditions A1 to D1 and the calculation formulas a1 to d1 can be changed as appropriate.

(Configuration of remote control 200)
The remote control 200 includes an operation unit 202, a display unit 203, a communication I/F 204, and a control unit 205. The operation unit 202 includes a plurality of buttons (not shown). A user of the air conditioning system 2 can input various instructions to the remote control 200 by operating the operation unit 202. For example, the user can input the temperature level of heating by the air conditioning system 2 by operating the operation unit 202. Information on the temperature level input to the remote control 200 is transmitted to the heat source unit 100 via the communication I/F 204.

The display unit 203 is a display for displaying various information. The display unit 203 may function as a touch panel (i.e., an operation unit). The display unit 203 displays, for example, the heating temperature level (e.g., level "4").

The communication I/F 204 is an interface for performing wired or wireless communication with the heat source unit 100. The control unit 205 has a storage unit (not shown) configured from a volatile memory, a non-volatile memory, etc., and controls the operation of each part of the remote control 200 according to a program stored in the storage unit.

(Tg determination process; FIG. 3)
Next, the Tg determination process executed by the control unit 106 of the heat source device 100 will be described. The Tg determination process is started, for example, when the heat source device 100 is powered on. As shown in Fig. 3, in S2 of the Tg determination process, the control unit 106 monitors whether or not new information on the detected temperature Ts has been acquired from the temperature sensor 105. Information on the detected temperature Ts of the temperature sensor 105 is transmitted to the control unit 106 at a predetermined time interval (for example, 10-minute intervals). If the control unit 106 has acquired new information on the detected temperature Ts (if YES), the process proceeds to S4. If the control unit 106 has not acquired new information on the detected temperature Ts (if NO), the process waits.

In the next step S4, the control unit 106 calculates new short-term average value Tg1 and long-term average value Tg2 based on the information on the detected temperature Ts obtained from the temperature sensor 105.

In the next step S6, the control unit 106 determines whether the new short-term average value Tg1 minus the (negative) long-term average value Tg2 is greater than a predetermined first threshold value (e.g., 5°C). If Tg1-Tg2>the first threshold value (YES), the process proceeds to S8. If Tg1-Tg2>the first threshold value is not (NO), the process proceeds to S10.

In the next step S8, the control unit 106 determines the new long-term average value Tg2 plus a predetermined correction value (e.g., 5°C) as the calculation reference value Tg. The predetermined correction value is a value equal to or less than the first threshold value (e.g., 5°C) in S6.

In S10 after NO in S6 above, the control unit 106 determines whether the new short-term average value Tg1 - (negative) long-term average value Tg2 is less than or equal to a predetermined first threshold value (e.g., 5°C) and greater than or equal to a predetermined second threshold value (e.g., -5°C). If the second threshold value ≦ Tg1 - Tg2 ≦ the first threshold value (YES), the process proceeds to S12. If the second threshold value ≦ Tg1 - Tg2 ≦ the first threshold value is not satisfied (NO (i.e., Tg1 - Tg2 < the second threshold value)), the process proceeds to S14. The second threshold value is the negative value of the first threshold value.

In the next step S12, the control unit 106 determines the new short-term average value Tg1 as the calculation reference value Tg. On the other hand, in step S14 after NO in step S10, the control unit 106 determines the new long-term average value Tg2 - (minus) a predetermined correction value (for example, 5°C) as the calculation reference value Tg. The predetermined correction value is a value equal to or less than the first threshold value (for example, 5°C) in step S10 and equal to or less than the absolute value of the second threshold value (for example, -5°C). When the processing in step S8, S12, or S14 is completed, the processing returns to S2.

(Heating temperature setting calculation process; Figure 4)
Next, a description will be given of the heating set temperature calculation process executed by the control unit 106 of the heat source unit 100. The heating set temperature calculation process is started, for example, when the heat source unit 100 is powered on. The heating set temperature calculation process is also executed, for example, when an automatic control mode for the heating set temperature is selected. In the air conditioning system 2, the user can select the automatic control mode for the heating set temperature by operating the operation unit 202 of the remote control 200.

As shown in FIG. 4, in S20 of the heating set temperature calculation process, the control unit 106 monitors whether or not new short-term average value Tg1 and long-term average value Tg2 have been calculated. New short-term average value Tg1 and long-term average value Tg2 are calculated in the process of S4 of the Tg determination process (see FIG. 3) described above. If new Tg1 and Tg2 have been calculated (YES), the process proceeds to S22. If new Tg1 and Tg2 have not been calculated (NO), the process waits.

In the next step S22, the control unit 106 calculates the heating reference temperature X. The control unit 106 calculates the heating reference temperature X based on the heating-related information 110 stored in the memory unit 107 and the calculation reference value Tg determined in the process of S8, S12, or S14 of the Tg determination process (see FIG. 3).

More specifically, the control unit 106 calculates the heating reference temperature X based on the calculation formulas a1 to d1 in the heating-related information 110 and the calculation reference value Tg determined in the Tg determination process. The control unit 106 calculates the heating reference temperature X based on the calculation formula (e.g., a1) that corresponds to the currently selected condition (e.g., A1) among the multiple calculation formulas a1 to d1.

In the next step S24, the control unit 106 calculates the heating set temperature Y based on the heating reference temperature X calculated in S22. For example, Y = X + 5°C x (heating temperature level (e.g., "4") - 4). The formula for calculating the heating reference temperature X can be changed as appropriate.

The control unit 106 controls the operation of each part of the heat source device 100 based on the information on the heating set temperature Y calculated in the process of S24. For example, the control unit 106 controls the opening degree of the three-way valve 55 of the heating unit 108 and the operation of the heat pump heat source 4 and the burner 31 of the combustion heat source 3 so that the temperature of the hot water supplied to the heating radiator 90 becomes the heating set temperature Y (see FIG. 2).

The above describes the air conditioning system 2 according to the embodiment. As is clear from the above description, in the air conditioning system 2, the control unit 106 of the heat source unit 100 determines the calculation reference value Tg based on the short-term average value Tg1, which is the average value of the temperature Ts detected by the temperature sensor 105 over the most recent two hours, and the long-term average value Tg2, which is the average value of the temperature Ts detected by the temperature sensor 105 over the most recent seven days (see FIG. 3). If Tg1-Tg2>first reference value (5°C), the control unit 106 sets Tg=Tg2+correction value (5°C). If Tg1-Tg2<second reference value (-5°C), the control unit 106 sets Tg=Tg2-correction value (5°C) (see FIG. 3). The control unit 106 calculates the heating setting temperature Y based on the calculation reference value Tg (see FIG. 4).

In the temperature sensor 105 that detects the outdoor temperature, the detected temperature Ts may become high or low in the short term due to the influence of the surrounding environment. For example, the detected temperature Ts may become high in the short term due to the influence of solar radiation, or may become low in the short term due to the influence of radiation cooling. According to the above configuration, the calculation reference value Tg is determined using a correction value (e.g., 5°C) according to the difference between the short-term average value Tg1 and the long-term average value Tg2 of the detected temperature Ts of the temperature sensor 105, so that it is possible to determine the calculation reference value Tg that reflects both the short-term temperature trend and the long-term temperature trend even when the difference between the short-term average value Tg1 and the long-term average value Tg2 is large. Then, by calculating the heating set temperature Y based on the calculation reference value Tg determined using the correction value, it is possible to prevent the heating set temperature Y from becoming extremely high or low in the short term, even if the detected temperature Ts of the temperature sensor 105 may become high or low in the short term. This reduces the load on the components of the heat source device 100 (e.g., the three-way valve 55 and the thermal valve 71).

When -5°C≦Tg1-Tg2≦5°C (i.e., when the absolute value of the difference between Tg1 and Tg2 does not exceed the threshold value (5°C)), the control unit 106 sets Tg=Tg1 (see FIG. 3). With this configuration, it is possible to calculate the heating setting temperature Y based on a temperature close to the current outdoor temperature.

The control unit 106 calculates the heating set temperature Y based on the calculation formulas a1 to d1 according to the heat transfer coefficient of the heating radiator 90 and the calculation reference value Tg. With this configuration, heating can be performed at the appropriate heating set temperature Y.

(Correspondence)
The combination of the heat source unit 100 and the heating radiator 90 (the first heating radiator 90a or the second heating radiator 90b) is an example of an "air conditioning device." The heat transfer coefficient of the heating radiator 90 is an example of an "air conditioning device capacity." The most recent two hours is an example of a "first period." The most recent seven days is an example of a "second period." The heating setting temperature Y is an example of an "air conditioning setting temperature."

(Modification)
(1) In the above embodiment, in the Tg determination process (see FIG. 3), when Tg1-Tg2>5° C., the control unit 106 sets Tg=Tg2+5° C. (see S6 and S8 in FIG. 3), but in a modified example, when Tg1-Tg2>5° C., the control unit 106 may set Tg=Tg1-5° C. In other words, the control unit 106 may determine, as Tg, a value obtained by subtracting a correction value (5° C.) from the higher value of Tg1 or Tg2.

(2) In the above embodiment, in the Tg determination process (see FIG. 3), the control unit 106 sets Tg = Tg2 - 5°C when Tg1 - Tg2 < -5°C (see S6, S10, S14 in FIG. 3). However, in a modified example, the control unit 106 may set Tg = Tg1 + 5°C when Tg1 - Tg2 < -5°C. In other words, the control unit 106 may set Tg to the lower of Tg1 and Tg2 plus a correction value (5°C).

As described in the embodiment and modified examples (1) and (2), when the absolute value of the difference between Tg1 and Tg2 exceeds a threshold value (e.g., 5°C), the control unit 106 determines the calculation reference value Tg to be the value obtained by adding a correction value (e.g., 5°C) to the lower value of Tg1 and Tg2. Alternatively, when the absolute value of the difference between Tg1 and Tg2 exceeds a threshold value (e.g., 5°C), the control unit 106 determines the calculation reference value Tg to be the value obtained by subtracting a correction value (e.g., 5°C) from the higher value of Tg1 and Tg2. Note that the correction value is equal to or less than the threshold value.

Although each embodiment has been described in detail above, these are merely examples and do not limit the scope of the claims. The technology described in the claims includes various modifications and variations of the specific examples exemplified above. The technical elements described in this specification or drawings exert technical utility alone or in various combinations, and are not limited to the combinations described in the claims at the time of filing. Furthermore, the technology exemplified in this specification or drawings can achieve multiple objectives simultaneously, and achieving one of those objectives is itself technically useful.

2: air conditioning system, 3: combustion heat source, 4: heat pump heat source, 7: heat exchange unit, 41: first heating path, 42: second heating path, 46: heating outlet hot water thermistor, 50: first circulation pump, 51: heat pump return path, 52: heating outward path, 53: heat pump outward path, 54: heating bypass path, 55: three-way valve, 57: heating return path, 60: second circulation pump, 70: heat exchanger, 71: thermal valve, 81: heat pump outlet hot water thermistor, 82: heat pump inlet water thermistor, 90: heating radiator, 100: heat source unit, 105: temperature sensor, 106: control unit, 107: memory unit, 108: heating unit, 200: remote control

Claims (3)

A temperature sensor for detecting an outdoor temperature;
an air conditioner that conditions the room at an air conditioning set temperature corresponding to the temperature detected by the temperature sensor;
A control unit that controls the air conditioning device,
the control unit is configured to determine a calculation reference value (Tg) based on a short-term average value (Tg1) which is an average value of the detected temperature of the temperature sensor in a first period and a long-term average value (Tg2) which is an average value of the detected temperature of the temperature sensor in a second period longer than the first period, and to calculate the air conditioning setting temperature of the air conditioner based on the calculation reference value (Tg);
The control unit is
When the absolute value of the difference between the short-term average value (Tg1) and the long-term average value (Tg2) exceeds a predetermined threshold value,
A value obtained by adding a correction value equal to or less than the threshold value to the lower value of the short-term average value (Tg1) and the long-term average value (Tg2) is determined as the calculation reference value (Tg); or
The air conditioning system determines the calculation reference value (Tg) by subtracting a correction value equal to or less than the threshold value from the higher of the short-term average value (Tg1) and the long-term average value (Tg2). The air conditioning system of claim 1, wherein the control unit determines the short-term average value (Tg1) as the calculation reference value (Tg) when the absolute value of the difference between the short-term average value (Tg1) and the long-term average value (Tg2) does not exceed the threshold value. 3. The air conditioning system according to claim 1, wherein the control unit is configured to calculate the air conditioning setting temperature of the air conditioning device based on a calculation formula according to a capacity of the air conditioning device and the calculation reference value (Tg).

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