JP2020112337A - Air conditioner - Google Patents

Abstract

To prevent a setting change based on a learning model from disturbing a use purpose of a user.SOLUTION: An air conditioner 2 includes a learning control section 23 and a control section 20. The learning control section 23 outputs a setting change instruction on the basis of a learning model. The control section 20 controls each section of the air conditioner 2 so that a set temperature set in the air conditioner 2 is changed on the basis of the setting change instruction. When an operation setting of the air conditioner 2 satisfies a predetermined condition, the control section 20 controls the air conditioner 2 so as not to change the set temperature on the basis of the setting change instruction.SELECTED DRAWING: Figure 4

Description

The present invention relates to an air conditioner.

An air conditioning system that automatically and efficiently controls air conditioning is known (Patent Document 1). In this air conditioning system, the storage unit has a learning function, and it is possible to reflect a suitable temperature environment in a time series according to the preference of the resident or the like, the action pattern, etc., in the control by the standard specification setting.

JP, 2005-117933, A

However, changing the setting of the air conditioner based on the learning model (for example, changing the operation mode, the set temperature, the set air volume, etc.) may not match the control of the air conditioner desired by the user.

The disclosed technology has been made in view of the above circumstances, and an object thereof is to provide an air conditioner that prevents a setting change based on a learning model from interfering with the control of an air conditioner desired by a user. To do.

An air conditioner in one aspect of the embodiment is an air conditioner, a learning control unit that outputs a setting change instruction based on a learning model, and a set value set in the air conditioner based on the setting change instruction. And a control unit that controls the air conditioner. The control unit controls the air conditioner so that the set value is changed based on the setting change instruction when the operation setting of the air conditioner satisfies a predetermined condition.

The disclosed air conditioner can prevent the setting change instruction based on the learning model from hindering the user's purpose of use.

FIG. 1 is an explanatory diagram showing an example of an air conditioning system provided with the air conditioner of the embodiment. FIG. 2 is a block diagram showing an example of the hardware configuration of the adapter. FIG. 3 is a block diagram showing the air conditioner. FIG. 4 is a flowchart showing the operation of controlling the air conditioner.

Hereinafter, an air conditioner according to an embodiment disclosed by the present application will be described with reference to the drawings. Note that the technology of the present disclosure is not limited to the following description. Further, in the following description, the same constituents will be given the same reference numerals and overlapping description will be omitted.

FIG. 1 is an explanatory diagram showing an example of an air conditioning system 1 provided with the air conditioner of the embodiment. The air conditioning system 1 includes an air conditioner 2, an adapter 3, an access point 4, a server device 5, a relay device 6, a communication terminal 7, and a communication network 8. The air conditioner 2 is a device that cools and heats a room. The communication terminal 7 is a terminal device such as a user's smartphone.

The adapter 3 has a communication function of connecting the air conditioner 2 and the access point 4 by wireless communication, and a control function of controlling the air conditioner 2 by AI (Artificial Intelligence). The access point 4 is a device that connects the adapter 3 and the communication network 8 by wireless communication using, for example, a WLAN (Wireless Local Area Network). The communication network 8 is, for example, a communication network such as the Internet. The server device 5 is an example of a service proposal timing adjustment device, and has a function of generating an AI learning model for controlling the air conditioner 2, a database for storing operation history data, and the like. The server device 5 is arranged in, for example, a data center. The relay device 6 has a function of connecting to the communication network 8 by communication and also connecting to the server device 5 by communication. The relay device 6 transmits from the adapter 3 to the server device 5 the operation history data and the like used for generating or updating the learning model applied to the air conditioner 2 via the communication network 8. The relay device 6 also transmits the learning model generated or updated by the server device 5 to the adapter 3 via the communication network 8. The relay device 6 is arranged, for example, in a data center or the like.

The relay device 6 has a first relay section 6A, a second relay section 6B, and a third relay section 6C. The first relay unit 6A relays various data related to AI control between the adapter 3 and the server device 5. The first relay unit 6A transmits the operation history data and the like used for generating or updating the learning model received from the adapter 3 to the server device 5 via the communication network 8, and at the same time, the learning model generated or updated by the server device 5 is transmitted. Is transmitted to the adapter 3 via the communication network 8. The second relay unit 6B acquires, via the communication network 8, the operating conditions of the air conditioner 2 (the operating mode such as cooling/heating, the set temperature, etc.) set by the user from the outside using the communication terminal 7. , And transmits this to the air conditioner 2 via the communication network 8. The third relay unit 6C acquires external data such as a weather forecast from the communication network 8 such as the Internet, and transmits the acquired external data to the server device 5, for example. The third relay unit 6C also transmits external data to the adapter 3 via the communication network 8.

FIG. 2 is a block diagram showing an example of the hardware configuration of the adapter 3. The adapter 3 illustrated in FIG. 2 includes a first communication unit 11, a second communication unit 12, a storage unit 13, and a CPU (Central Processing Unit) 14. The first communication unit 11 is a communication IF (Interface) such as, for example, a UART (Universal Asynchronous Receiver Transmitter) that is communicatively connected to the air conditioner 2. The second communication unit 12 is, for example, a communication IF such as a WLAN that is communicatively connected to the access point 4. The storage unit 13 includes, for example, a ROM (Read Only Memory) and a RAM (Random Access Memory), and stores various information such as data and programs. The CPU 14 controls the entire adapter 3.

The CPU 14 includes a transmitter 21, a receiver 22, and a learning controller 23. The transmission unit 21 includes a plurality of set values set in the air conditioner 2 (for example, an operation mode such as a cooling operation and a heating operation, a set temperature, a set air volume), and a plurality of operation history data corresponding to a plurality of dates and times. Are collected from the air conditioner 2, and the plurality of set values and the plurality of operation history data thus collected are stored in the storage unit 13. The operation history data corresponding to a certain date and time among the plurality of operation history data includes operation settings (for example, operation mode, set temperature, set air volume, etc.) at which the air conditioner 2 operates at that date and time, and Detected by a sensor provided in the air conditioner 2 and operation settings input to the air conditioner 2 (for example, operation mode, set temperature, set air volume changed by the user according to changes in the outside temperature, etc.) The detected results (for example, indoor temperature, indoor humidity, indoor heat exchanger temperature, outdoor air temperature, outdoor air humidity, outdoor heat exchanger temperature, etc.) are shown. The transmission unit 21 creates driving status information indicating a plurality of set values and a plurality of driving history data stored in the storage unit 13, and sends the created driving status information to the server device 5 via the communication network 8. Send to.

The receiving unit 22 receives the learning model from the server device 5 via the communication network 8 and stores the received learning model in the storage unit 13. The learning model includes a cooling learning model and a heating learning model. The learning control unit 23 outputs a cooling setting change instruction based on the cooling learning model stored in the storage unit 13, and outputs a heating setting change instruction based on the heating learning model stored in the storage unit 13. To do. The cooling setting change instruction indicates a “sensible temperature up instruction” or a “sensible temperature down instruction”. Similar to the cooling setting change instruction, the heating setting change instruction also indicates a “sensible temperature up instruction” or a “sensible temperature down instruction”. The “instruction to increase the sensible temperature” means that the learning control unit 23 instructs the air conditioner 2 to perform an operation such that the sensible temperature of the user rises. The “sensible temperature down instruction” means that the learning control unit 23 instructs the air conditioner 2 to perform an operation such that the user's sensible temperature decreases. The learning control unit 23 outputs the outputted cooling setting change instruction and heating setting change instruction to the air conditioner 2.

As the learning model, for example, the sensible temperature setting for predicting the sensible temperature after 5 minutes for the user in the room according to the operating condition of the air conditioner in each home and controlling the air conditioner according to the predicted sensible temperature is set. There is a predictive model. The sensible temperature setting prediction model is a program executed when adjusting the air conditioner so that the user feels comfortable according to the time-series indoor temperature, indoor humidity, outdoor temperature, and the like. For example, the air conditioner is controlled based on the sensible temperature setting prediction model, so that the set temperature of the air conditioner is changed so that the user feels comfortable. The air conditioner 2 is controlled based on such a sensible temperature setting prediction model, so that the air conditioner 2 can be appropriately cooled and heated so that the user is comfortable.

FIG. 3 is a block diagram showing the air conditioner 2. As shown in FIG. 3, the air conditioner 2 includes an indoor unit 15, an outdoor unit 16, a temperature sensor 17, a human sensor 18, a remote controller 19, and a control unit 20. The indoor unit 15 is arranged indoors and further includes an indoor fan, a filter, a filter cleaning mechanism, and an indoor heat exchanger, which are not shown. The indoor fan generates a flow of air that the indoor air in which the indoor unit 15 is disposed passes through the indoor heat exchanger, and blows the air that has passed through the indoor heat exchanger into the room. The filter collects dust from the air before passing through the indoor heat exchanger. The filter cleaning mechanism removes dust repaired by the filter from the filter. The indoor heat exchanger heats or cools the indoor air by exchanging heat between the refrigerant supplied from the outdoor unit 16 and the air whose flow is generated by the indoor fan. The indoor unit 15 cools or heats the room by the indoor heat exchanger heating or cooling the air in the room.

The outdoor unit 16 is arranged outdoors and includes an outdoor fan, an outdoor heat exchanger, a compressor, and an expansion valve (not shown). The outdoor fan generates a flow of air through which the outdoor air in which the outdoor unit 16 is arranged passes through the outdoor heat exchanger. The outdoor heat exchanger heats or cools the refrigerant by exchanging heat between the outside air whose flow is generated by the outdoor fan and the refrigerant. The compressor circulates the refrigerant between the indoor unit 15 and the outdoor unit 16. The expansion valve adjusts the opening thereof to adjust the amount of refrigerant flowing into the indoor unit 15. The outdoor unit 16 supplies the refrigerant cooled or heated by the outdoor heat exchanger to the indoor unit 15 by the compressor circulating the refrigerant between the indoor unit 15 and the outdoor unit 16.

The temperature sensor 17 is provided in the indoor unit 15 and measures the temperature of the room in which the indoor unit 15 is arranged. The human sensor 18 is provided in the indoor unit 15, detects whether a person or a pet is present in the room in which the indoor unit 15 is arranged, and detects the "absence state" or the "occupancy state". The remote controller 19 includes an operation unit and a display unit, which are not shown. The remote controller 19 outputs information generated by operating the operation unit to the control unit 20, and operation information of the operation unit, detection results of various sensors such as room temperature, and information generated by the control unit 20. Is displayed on the display so that the user can recognize it.

The control unit 20 is a computer, stores a plurality of setting values, controls each unit of the air conditioner 2, and communicates with the adapter 3. For example, the control unit 20 changes a plurality of setting values by operating the remote controller 19, and changes a plurality of setting values based on the information acquired from the communication terminal 7 via the communication network 8 and the adapter 3. The plurality of set values include set temperatures. The control unit 20 further controls the indoor unit 15 and the outdoor unit 16 so that the indoor unit 15 heats the room based on the set temperature when “heating” is selected by operating the remote controller 19. The control unit 20 controls the indoor unit 15 and the outdoor unit 16 so that the indoor unit 15 cools the room based on the set temperature when “cooling” is selected by the operation of the remote controller 19. The control unit 20 controls the indoor unit 15 and the outdoor unit 16 so that the indoor unit 15 stops heating and cooling when “stop” is selected by operating the remote controller 19.

The control unit 20 further detects whether there is a person or a pet in the room in which the indoor unit 15 is placed when the “absent eco mode” is set in the air conditioner 2 by operating the remote controller 19. Then, the human sensor 18 is controlled. When the "absence eco mode" is set for the air conditioner 2 and the "absence state" is detected by the human sensor 18, the control unit 20 saves power when the respective parts of the air conditioner 2 are saved. To control.

When the "good night timer mode" is set in the air conditioner 2 by operating the remote controller 19, the control unit 20 further changes the set temperature every predetermined time. For example, the control unit 20 changes the set temperature so that the set temperature is increased by a predetermined temperature every predetermined time when the “good night timer mode” is set when the air conditioner 2 is being cooled. To do. The control unit 20 changes the set temperature so that the set temperature decreases by the predetermined temperature every predetermined time when the "good night timer mode" is set when the air conditioner 2 is heated.

The control unit 20 further causes the outdoor unit 16 to be defrosted, that is, the outdoor heat exchanger of the outdoor unit 16 to be heated, when “defrost” is set in the air conditioner 2. , And controls the indoor unit 15 and the outdoor unit 16. The air conditioner 2 stops heating when heating the outdoor heat exchanger, and at this time, the temperature inside the room may decrease. In order to suppress such a decrease in temperature, the air conditioner 2 may perform hot keep defrosting in which the outdoor heat exchanger is heated strongly in advance before being heated.

The control unit 20 further controls the temperature sensor 17 so that the temperature inside the room is intermittently measured. The control unit 20 calculates the room temperature Tr measured by the temperature sensor 17 based on the operation setting of the air conditioner 2. The control unit 20 further stores an upper limit value for cooling, a lower limit value for cooling, an upper limit value for heating, and a lower limit value for heating. Here, the upper limit value for cooling means the highest temperature among the set temperatures previously set by the user during the cooling operation. Further, the lower limit value for cooling means the lowest temperature among the set temperatures previously set by the user during the cooling operation. Furthermore, the heating upper limit value refers to the highest temperature among the preset temperatures previously set by the user during the heating operation. Further, the heating lower limit value is the lowest temperature among the set temperatures previously set by the user during the heating operation.

[Operation of the air conditioning system 1]
The operation of the air conditioning system 1 includes an operation of continuously learning the learning model and continuously improving the learning model, and an operation of controlling the air conditioner 2.

In the operation of continuously learning the learning model, the adapter 3 acquires the operation history data from the control unit 20 of the air conditioner 2 at the acquisition timing of the 5-minute cycle, and stores the acquired operation history data in the storage unit 13. Remember. The adapter 3 further acquires a plurality of set values from the control unit 20 of the air conditioner 2, and stores the acquired plurality of set values in the storage unit 13. The adapter 3 creates driving status information every predetermined time (for example, every 48 hours), and transmits the created driving status information to the server device 5 via the communication network 8. The driving status information indicates the driving history data for 48 hours out of the driving history data stored in the storage unit 13 and the set values. Upon receiving the driving condition information transmitted from the adapter 3, the server device 5 stores the driving condition information in the storage device 32. The server device 5 continuously learns the learning model based on the driving situation information stored in the storage device 32, and stores the conventionally improved learning model (latest learning model) in the storage device 32. The latest learning models include a cooling learning model and a heating learning model. The server device 5 transmits the latest learning model stored in the storage device 32 to the adapter 3 via the relay device 6. When the adapter 3 receives the latest learning model transmitted from the server device 5, the adapter 3 stores the received latest learning model in the storage unit 13.

FIG. 4 is a flowchart showing the operation of controlling the air conditioner 2. The adapter 3 outputs a cooling setting change instruction to the air conditioner 2 based on the cooling learning model stored in the storage unit 13, and changes the heating setting based on the heating learning model stored in the storage unit 13. An instruction is output (step S1). The adapter 3 outputs the cooling setting change instruction and the heating setting change instruction output to the air conditioner 2 to the air conditioner 2.

Upon receiving the cooling setting change instruction and the heating setting change instruction output from the adapter 3, the control unit 20 of the air conditioner 2 determines whether the operation setting of the air conditioner 2 satisfies a predetermined condition. Yes (step S2). That is, the control unit 20 determines whether the cooling operation or the heating operation is being performed. The control unit 20 further determines whether the following expression (1) is satisfied based on the room temperature Tr measured by the temperature sensor 17 and the set temperature.
(Set temperature) −1.5° C.≦Tr≦ (Set temperature)+1.5° C. (1)

The control unit 20 further determines whether the set temperature is higher than the upper limit value for cooling while the air conditioner 2 is cooling, and determines whether the set temperature is lower than the lower limit value for cooling. To do. When the air conditioner 2 is still heating, the control unit 20 determines whether the set temperature is higher than the heating upper limit value and determines whether the set temperature is lower than the heating lower limit value. To do. The control unit 20 further determines whether or not the “good night timer mode” is set for the air conditioner 2. The control unit 20 further determines whether or not the “absent eco mode” is set for the air conditioner 2. The control unit 20 determines whether the "absence state" or the "in-room state" is detected by the human sensor 18 when the "absence eco mode" is set in the air conditioner 2. The control unit 20 further determines whether or not the air conditioner 2 is being defrosted.

The controller 20 determines that the operation setting does not satisfy the predetermined condition when the room temperature Tr does not satisfy the expression (1). When the expression (1) is not satisfied, it is considered that the air conditioner 2 is in the process of operating so that the indoor temperature approaches the user's set temperature. Therefore, if the set value of the air conditioner 2 is changed under such a condition, the comfort of the user may be impaired. Therefore, when the room temperature Tr does not satisfy the expression (1), it is determined that the operation setting does not satisfy the predetermined condition, and the control unit 20 does not accept the cooling setting change instruction and the heating setting change instruction.

The control unit 20 further determines that the operation setting does not satisfy the predetermined condition when the “good night timer mode” is set in the air conditioner 2. When the “absent eco mode” is set in the air conditioner 2 and the human sensor 18 detects the “absence state”, the control unit 20 does not satisfy the predetermined condition in the operation setting. judge. The control unit 20 further determines that the operation setting does not satisfy the predetermined condition when the set temperature is higher than the cooling upper limit value when the air conditioner 2 is further cooling.

The control unit 20 determines that the operation setting does not satisfy the predetermined condition when the air conditioner 2 is further cooling and the set temperature is lower than the cooling lower limit value. When the air conditioner 2 is further heated, the control unit 20 determines that the operation setting does not satisfy the predetermined condition when the set temperature is higher than the heating upper limit value. When the air conditioner 2 is further heated, the control unit 20 determines that the operation setting does not satisfy the predetermined condition when the set temperature is lower than the heating lower limit value. The control unit 20 further determines that the operation setting does not satisfy the predetermined condition when the air conditioner 2 is being defrosted.

On the other hand, when determining that the operation setting of the air conditioner 2 satisfies the predetermined condition (Yes in step S2), the control unit 20 changes the set temperature based on the cooling setting change instruction or the heating setting change instruction. (Step S3). That is, the controller 20 changes the set temperature based on the cooling setting change instruction when the operation setting of the air conditioner 2 satisfies the predetermined condition and the air conditioner 2 is cooling. Specifically, the control unit 20 indicates that when the operation setting of the air conditioner 2 does not satisfy the predetermined condition and the air conditioner 2 is cooling, the cooling setting change instruction indicates a “perceived temperature increase instruction”. At this time, the set temperature is changed so that the set temperature is increased by 0.5 degrees, for example. For example, when the operation setting of the air conditioner 2 does not satisfy the predetermined condition and the air conditioner 2 is cooling and the cooling setting change instruction indicates “a sensible temperature down instruction”, for example, The set temperature is changed so that the set temperature is lowered by 0.5 degree.

In addition, the control unit 20 changes the set temperature based on the heating setting change instruction when the operation setting of the air conditioner 2 satisfies the predetermined condition and the air conditioner 2 is heating. Specifically, the control unit 20 is in a case where the operation setting of the air conditioner 2 satisfies a predetermined condition and the air conditioner 2 is heating, and when the heating setting change instruction indicates a “sensible temperature up instruction”. For example, the set temperature is changed so that the set temperature increases by 0.5 degrees. When the operation setting of the air conditioner 2 satisfies a predetermined condition and the air conditioner 2 is heating, and the instruction for changing the heating setting indicates the “instruction to decrease the sensible temperature”, for example, the control unit 20 sets the set temperature. Change the set temperature so that is 0.5 degrees lower.

When it is determined that the operation setting of the air conditioner 2 does not satisfy the predetermined condition (No in step S2), the control unit 20 does not change the set temperature based on the cooling setting changing instruction or the heating setting changing instruction. Thus, the air conditioner 2 is controlled. Specifically, the control unit 20 maintains the set temperature by not accepting the cooling setting changing instruction or the heating setting changing instruction.

Therefore, in the air conditioner 2, the set temperature is not changed by the learning model when the "good night timer mode" is set, and the set temperature is appropriately changed every predetermined time, for example, in the room. It is possible to prevent the occurrence of too cold or too warm. In the air conditioner 2, the set temperature is not changed by the learning model when the “absence eco mode” is set and the human sensor 18 detects the “absence state”. You can save power properly. A user does not necessarily aim to improve comfort, but may use the air conditioner 2 for purposes other than comfort. At this time, the set temperature does not satisfy the expression (1) or is out of the range between the upper and lower limit values. The air conditioner 2 does not change the set temperature by the learning model when the formula (1) is not satisfied, or when the set temperature is out of the range between the upper and lower limit values, and the user cools and heats the room. It is possible to prevent hindering the purpose of doing so. In the present embodiment, the cooling setting change instruction and the heating setting change instruction are simultaneously output to the air conditioner 2, and it is determined which change instruction the air conditioner 2 receives the change instruction receives. The present invention is not limited to this. Therefore, for example, the cooling setting change instruction may be output only during the cooling operation, and the heating setting change instruction may be output only during the heating operation.

[Effects of the air conditioner 2 of the embodiment]
The air conditioner 2 of the embodiment includes an indoor unit 15, a learning control unit 23, and a control unit 20. The indoor unit 15 cools and heats the room. The learning control unit 23 outputs a setting change instruction based on the learning model. The control unit 20 receives an instruction to change the setting temperature of the air conditioner 2 when the operation setting of the air conditioner 2 satisfies a predetermined condition. The control unit 20 controls each unit of the air conditioner 2 so that the set temperature is changed based on the setting change instruction. The control unit 20 does not accept the setting change instruction when the operation setting of the air conditioner 2 does not satisfy the predetermined condition. Since the control unit 20 does not receive the setting change instruction, the set temperature is not changed based on this instruction. At this time, the air conditioner 2 prevents the set temperature from being changed by the learning model when the user cools or heats for a purpose other than comfort (for example, when the absence eco-mode is set). It is possible to prevent the achievement of the user's purpose (for example, power saving operation) from being hindered.

Further, the control unit 20 of the air conditioner 2 of the embodiment prevents the set temperature from being changed based on the setting change instruction when the “good night timer mode” is set (when the predetermined condition is not satisfied). , Controls each part of the air conditioner 2. The control unit 20 controls the air conditioning so that the set temperature is changed based on the setting change instruction when the “good night timer mode” is not set in each unit of the air conditioner 2 (when the predetermined condition is satisfied). Control each part of the machine 2. At this time, the air conditioner can prevent the achievement of the operation purpose of the air conditioner 2 by the user's setting of the "good night timer mode" from being hindered by the control by the learning model, and the room can be cooled too much. It is possible to prevent overheating.

In addition, the air conditioner 2 of the embodiment includes the human sensor 18 that detects the “absence state” or the “occupancy state”. When the "absence eco-mode" is set and the human sensor 18 detects the "absence state" (when the predetermined condition is not satisfied), the control unit 20 sets the set temperature based on the setting change instruction. Each part of the air conditioner 2 is controlled so as not to be changed. When the "absence-free eco mode" is set, the control unit 20 changes the air temperature so that the set temperature is changed based on the setting change instruction when the human sensor 18 detects the "in-room state". Control each part of the harmony machine 2. The control unit 20 controls each unit of the air conditioner 2 so that the set temperature is changed based on the setting change instruction when the “absent eco mode” is not set (when the predetermined condition is satisfied). .. At this time, the air conditioner 2 can prevent the achievement of the operation purpose of the air conditioner 2 by the user's setting of "absent eco mode" from being hindered by the control by the learning model, and the power saving can be appropriately performed. can do.

Further, the control unit 20 of the air conditioner 2 of the embodiment causes the set temperature to be changed based on the setting change instruction when the air conditioner 2 is not defrosted (when the predetermined condition is satisfied). , Controls each part of the air conditioner 2. The control unit 20 controls each unit of the air conditioner 2 so that the set temperature is not changed based on the setting change instruction when the air conditioner 2 is defrosting (when the predetermined condition is not satisfied). .. At this time, the air conditioner 2 can prevent the defrosting of the outdoor unit from being hindered by the control by the learning model, and can appropriately defrost the outdoor unit 16.

Further, the control unit 20 of the air conditioner 2 of the embodiment controls each unit of the air conditioner 2 so that the room is cooled and heated based on the set temperature. At this time, the control unit 20 does not accept the cooling setting change instruction or the heating setting change instruction when the difference between the room temperature Tr and the set temperature is not included in the predetermined range (when the predetermined condition is not satisfied). On the other hand, when the set temperature is within the predetermined range (when the predetermined condition is satisfied), the set temperature is changed based on the cooling setting change instruction or the heating setting change instruction. At this time, it is possible to prevent the control by the learning model from interfering with the achievement of the user's purpose.

Further, the cooling setting change instruction or the heating setting change instruction of the air conditioner 2 of the embodiment indicates a “sensible temperature up instruction” or a “sensible temperature down instruction”. The control unit 20 does not change the set temperature when the "sensible temperature up instruction" as the setting change instruction is output and the heating is performed and the set temperature is higher than the heating upper limit value. On the other hand, when the set temperature is not higher than the heating upper limit value, the set temperature is changed so that the set temperature becomes higher. The control unit 20 does not change the set temperature when the “sensible temperature up instruction” as the setting change instruction is output and the cooling is performed and the set temperature is higher than the upper limit value for cooling. On the other hand, when the set temperature is not higher than the cooling upper limit value, the set temperature is changed so that the set temperature becomes higher. The control unit 20 does not change the set temperature when the "sensible temperature down instruction" is output as these setting change instructions and the heating is performed and the set temperature is lower than the heating lower limit value. On the other hand, when the set temperature is not lower than the heating lower limit value, the set temperature is changed so that the set temperature becomes lower. The control unit 20 does not change the set temperature when the "feeling temperature down instruction" as the setting change instruction is output and the heating is performed and the set temperature is lower than the cooling lower limit value. On the other hand, when the set temperature is not lower than the cooling lower limit value, the set temperature is changed so that the set temperature becomes lower. Also in this case, the air conditioner 2 is set by the user by not accepting the cooling setting change instruction or the heating setting change instruction when the difference between the room temperature Tr and the set temperature is not within the predetermined range. It is possible to maintain the preset temperature and prevent the control by the learning model from interfering with the achievement of the user's purpose.

Further, the learning model of the air conditioner 2 of the embodiment includes a cooling learning model that outputs a cooling setting change instruction and a heating learning model that outputs a heating setting change instruction. When the air conditioner 2 is heating the room, the control unit 20 does not receive the cooling setting change instruction, but does receive the heating setting change instruction. When the air conditioner 2 is cooling the room, it does not receive the heating setting change instruction but receives the cooling setting change instruction. At this time, the learning control unit 23 of the adapter 3 does not need to select one of the learning model for cooling and the learning model for heating, and can easily output the setting change instruction.

By the way, the control unit 20 and the adapter 3 of the air conditioner 2 of the above-described embodiment are separate, but may be formed by one control device. Also in this case, the air conditioner 2 can prevent the achievement of the purpose of the user from being hindered by not changing the set temperature when the operation setting satisfies the predetermined condition.

By the way, the control unit 20 of the air conditioner 2 of the above-described embodiment changes the set temperature when the "sensible temperature increase instruction" or the "sensible temperature down instruction" is output by the learning model. However, other setting values may be changed. The wind direction and the flow rate are exemplified as the set values. For example, the control unit 20 controls the indoor unit 15 to increase the air volume so that the wind direction is toward the person when the cooling setting change instruction indicates “a sensible temperature down instruction” during cooling. Good. Even if the control unit 20 controls the indoor unit 15 to decrease the air volume so that the wind direction is in the direction where there is no person when the air conditioner setting change instruction indicates the “perceived temperature increase instruction” during cooling. Good. Even when the control unit 20 controls the indoor unit 15 to decrease the air volume so that the wind direction is in the direction where there is no person when the heating setting change instruction indicates the “perceived temperature down instruction” during heating. Good. The control unit 20 may control the indoor unit 15 such that the wind direction is directed toward the person and the air volume is increased when the heating setting change instruction indicates the “perceived temperature increase instruction” during heating. .. When the operation setting of the air conditioner 2 satisfies a predetermined condition, the control unit 20 controls the indoor unit 15 so that the wind direction and the flow rate are changed based on the cooling setting change instruction and the heating setting change instruction. To do. Also in this case, the air conditioner 2 can prevent the achievement of the purpose of the user from being hindered by not changing the set value when the operation setting does not satisfy the predetermined condition.

Although the embodiment has been described above, the embodiment is not limited to the contents described above. Further, the components described above include those that can be easily conceived by those skilled in the art, those that are substantially the same, and those within the so-called equivalent range. Furthermore, the components described above can be combined appropriately. Furthermore, at least one of various omissions, substitutions, and changes of the constituent elements can be made without departing from the spirit of the embodiment.

1: Air conditioning system 2: Air conditioner 3: Adapter 15: Indoor unit 16: Outdoor unit 17: Temperature sensor 18: Human sensor 20: Control unit 21: Transmission unit 22: Reception unit 23: Learning control unit

Claims (8)

An air conditioner,
A learning control unit that outputs a setting change instruction based on a learning model,
A set value that is set in the air conditioner is changed based on the setting change instruction, and a control unit that controls the air conditioner is provided,
The control unit controls the air conditioner such that the set value is changed based on the setting change instruction when the operation setting of the air conditioner satisfies a predetermined condition. The control unit is
When the sleep timer mode is set in the air conditioner, the air conditioner is controlled so that the set value is not changed based on the setting change instruction,
The air conditioner according to claim 1, wherein the air conditioner is controlled so that the set value is changed based on the setting change instruction when the sleep timer mode is not set in the air conditioner. .. The air conditioner has a human sensor for detecting an absent state or a room state,
The control unit is
When the absence eco mode is not set in the air conditioner, the set value is changed based on the setting change instruction, the air conditioner is controlled,
In the case where the absence eco-mode is set in the air conditioner, when the human sensor detects the presence state of the room, the set value is changed based on the setting change instruction, Control the air conditioner,
In the case where the absence eco mode is set in the air conditioner, when the human sensor detects the absence condition, the air conditioner is configured so that the set value is not changed based on the setting change instruction. The air conditioner according to claim 1, wherein the air conditioner is controlled. The control unit is
When the air conditioner is not defrosting, so that the set value is changed based on the setting change instruction, controlling the air conditioner,
The air conditioner according to claim 1, wherein the air conditioner is controlled so that the set value is not changed based on the setting change instruction when the air conditioner is defrosting. The control unit is
To control the air conditioner based on the set temperature, control the air conditioner,
When the difference between the room temperature and the set temperature is not included in the predetermined range, the set temperature is not changed based on the setting change instruction,
The air conditioner according to claim 1, wherein the set temperature is changed based on the setting change instruction when the difference between the indoor temperature and the set temperature is included in the predetermined range. The air conditioner according to claim 5, wherein the air conditioner includes a temperature sensor that measures the indoor temperature. The setting change instruction indicates a sensible temperature up instruction or a sensible temperature down instruction,
The control unit is
The highest temperature among the set temperatures that the user has set in the past during cooling operation is the upper limit value for cooling, and the lowest temperature is the lower limit value for cooling, when the set temperature is higher than the upper limit value for cooling, The air conditioner according to claim 5, wherein the set temperature is not changed when the temperature is lower than the cooling lower limit value. The learning model is
A learning model for cooling that outputs a setting change instruction for cooling,
Including a heating learning model that outputs a setting change instruction for heating,
The control unit is
While the air conditioner is heating, while changing the setting value based on the heating setting change instruction, while not accepting the cooling setting change instruction,
While the air conditioner is cooling, while changing the setting value based on the cooling setting change instruction, do not accept the heating setting change instruction,
The air conditioner according to any one of claims 1 to 7.

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