JP6713880B2 - Air conditioning system and terminal equipment - Google Patents

Description

The present invention relates to an air conditioning system and the like.

BACKGROUND ART Conventionally, various technologies for providing a comfortable environment to a user have been proposed in the field of home electric appliances (particularly air conditioners). For example, in order to provide the user with a comfortable sleeping environment, a technique for controlling the operation of various home appliances has been proposed.

As an example, Patent Document 1 discloses an air conditioner that controls temperature when a user sleeps, for the purpose of improving comfort when the user sleeps.

Further, Patent Literature 2 discloses a home electric appliance control system that controls at least one of illuminance and color tone of a lighting device in cooperation with operation of an air conditioner in order to improve comfort of an indoor environment.

Further, Patent Document 3 discloses a sleeping directional light source and a sound source supply device that are installed around the bed of a user (sleeping person). The respective devices of Patent Document 3 are intended to bring a user to sleep comfortably, sleep deeply, and wake up.

In addition, Patent Document 4 discloses an indoor environment control system that controls an indoor environment control device in accordance with user biometric information that changes with time.

JP 2007-192450 A (Published August 2, 2007) JP, 2014-216835, A (Published November 17, 2014) Japanese Patent Laid-Open No. 2015-27329 (Published February 12, 2015) JP, 2013-213642, A (published on October 17, 2013)

However, there is still room for improvement in the method of linking the air conditioner and the peripheral devices for providing the user with a more comfortable sleeping environment. An object of the present invention is to realize an air conditioning system or the like that can provide a user with a more comfortable sleeping environment than before.

In order to solve the above problems, an air conditioning system according to one aspect of the present invention, an air conditioner that performs air conditioning in a room, peripheral devices provided in the room, a terminal device, and via a communication network, An air conditioning system including the air conditioner and a server device connected to the terminal device, wherein the server device includes an air conditioning control unit that controls the air conditioner, and the air conditioner is , A peripheral device control unit for controlling the peripheral device is provided, the terminal device is provided with a mode setting unit for switching the operation mode of the air conditioner, the operation mode is suitable for sleep of the user A sleep preparation mode that is a mode of providing an indoor environment is included, and when the mode setting unit switches the operation mode to the sleep preparation mode, the air conditioning control unit causes the air conditioner to prepare for the sleep. A first command to operate in the mode is given to the air conditioner, and the peripheral device control section gives a second command corresponding to the first command to the peripheral device.

In order to solve the above problems, in a terminal device according to an aspect of the present invention, a server device causes an air conditioner that performs air conditioning in a room to perform an operation according to a predetermined operation mode, Is a terminal device that cooperates with an air conditioning system configured to control the operation of peripheral equipment provided in the room, and sets at least a display unit that displays an image and the operation mode of the air conditioner. And a communication unit that communicates with the server device. The air conditioner and the peripheral devices are provided in the operation mode of the air conditioner so as to provide an indoor environment suitable for the user to fall asleep. Includes a sleep preparation mode that is a mode for setting each operation of, and the mode setting unit, when displaying a driving mode setting screen for the user to set the driving mode on the display unit, the sleep Displays a button to set the preparation mode.

The air conditioning system according to one aspect of the present invention has the effect of providing the user with a more comfortable sleeping environment than before.

Further, the terminal device according to one aspect of the present invention also has the same effect.

It is a figure showing an outline of an air-conditioning system concerning Embodiment 1 of the present invention. It is a functional block diagram which shows the structure of the principal part of the air conditioning system of FIG. It is a figure which shows an example of the screen displayed on the display part before the sound sleep application is started in the portable terminal of the air conditioning system of FIG. It is a figure which shows an example of the screen displayed on the display part after the sound sleep application was started in the portable terminal of the air conditioning system of FIG. It is a figure which shows an example of the screen displayed on the display part according to a user's selection during execution of the sleep application in the portable terminal of the air conditioning system of FIG. It is a figure which shows the variation of the direction of the air blown out indoors from the airflow panel of an air conditioner in the air conditioning system of FIG. It is a sequence diagram which illustrates the flow of a process from sleep preparation to getting up in the air conditioning system of FIG. It is a figure which illustrates the time chart which shows the schedule of the time change of the preset temperature of the air conditioner in a sleep mode in the air conditioning system of FIG. It is a functional block diagram which shows the structure of the principal part of the air conditioning system which concerns on Embodiment 2 of this invention.

[Embodiment 1]
Hereinafter, Embodiment 1 of the present invention will be described in detail with reference to FIGS. FIG. 1 is a diagram showing an outline of an air conditioning system 100 of this embodiment. First, an outline of the air conditioning system 100 will be described with reference to FIG.

(Outline of air conditioning system 100)
The air conditioning system 100 includes a mobile terminal 10 (terminal device), a cloud server 20 (server device), an air conditioner 30, and peripheral devices 40. The air conditioner 30 and the peripheral device 40 are provided in the same room of the user's house. Hereinafter, the case where the air conditioner 30 and the peripheral device 40 are provided in the bedroom will be described as an example.

As described below, in the air conditioning system 100, the mobile terminal 10 gives the cloud server 20 a mode switching command for switching the operation mode of the air conditioner 30. Then, when the operation mode is switched to a predetermined operation mode (for example, a sleep preparation mode or a sleep mode described below), (i) the cloud server 20 gives the first instruction to the air conditioner 30, and (ii) ) The air conditioner 30 gives the peripheral device 40 a second command corresponding to the first command.

The mobile terminal 10 (one specific example of the terminal device) of the present embodiment is, for example, a smartphone (mobile phone). However, the terminal device according to one embodiment of the present invention is not limited to a mobile phone. The terminal device may be a remote controller for a user to remotely operate the air conditioner 30, or may be a portable information processing device such as a notebook PC (Personal Computer) or a tablet PC.

The cloud server 20 is connected to the mobile terminal 10 via the (i) communication network 90a and the air conditioner 30 via the (ii) communication network 90b. Therefore, the mobile terminal 10 can operate the air conditioner 30 (more specifically, change the operation mode of the air conditioner 30) via the cloud server 20.

The communication networks 90a and 90b may be collectively referred to as the communication network 90. A well-known communication technique (eg, wireless LAN technique) may be used for the communication network 90.

An application for operating the air conditioner 30 via the cloud server 20 (hereinafter referred to as a “sleep sleep application”) is pre-installed on the mobile terminal 10.

In the mobile terminal 10, the mode setting unit 14 (described later) displays the operation mode setting screen (screen of the sleep app) for allowing the user to set (select) the operation mode of the air conditioner 30 on the display unit 11a (described later). Display it. In addition, the mode setting unit 14 causes the display unit 11a to display various buttons (input images) for the user to set the operation mode on the screen of the sleep app.

In addition, a program for controlling the air conditioner 30 (hereinafter referred to as a “sleep sleep program”) is installed in the cloud server 20 in response to a mode switching command from the mobile terminal 10.

The air conditioner 30 is a device that air-conditions a room (eg, bedroom), and is, for example, an air conditioner. A home appliance adapter (not shown) is previously attached to the air conditioner 30 in order to communicate with the cloud server 20. The air conditioner 30 and the home appliance adapter may be integrated.

Further, the air conditioner 30 includes an infrared sensor 35 (sensor). The infrared sensor 35 may be arranged on the front surface of the housing of the air conditioner. As described below, the infrared sensor 35 functions as a motion sensor that detects the presence of the user in the bedroom. However, the sensor according to one embodiment of the present invention is not limited to the infrared sensor. The sensor may have any function as a human sensor.

The peripheral device 40 is various home appliances provided in the bedroom (in the same room as the air conditioner 30). In FIG. 1, a lighting device 41 is shown as a component of the peripheral device 40. As shown in FIG. 2 to be described later, in the present embodiment, a description will be given by exemplifying a case where the peripheral device 40 includes a lighting device 41, a television 42 (sound device), and an aroma generator 43 (odor generator). To do. However, the illumination device 41 to the aroma generator 43 are examples of the peripheral device 40, and the peripheral device 40 is not limited to these and may be any device that is involved in creating a sleep environment.

A home appliance adapter (not shown) may be attached to the peripheral device 40 in advance in order to communicate with the air conditioner 30. The peripheral device 40 and the home appliance adapter may be integrated.

By the way, some home appliances (particularly the lighting device 41 and the television 42) may be configured to be operable by an infrared remote controller. Based on this point, the air conditioner 30 and the peripheral device 40 may be configured to communicate using a known infrared communication technology.

In this case, the peripheral device 40 can acquire the second command from the air conditioner 30 by infrared communication. Therefore, the peripheral device 40 does not require a home appliance adapter for communicating with the air conditioner 30. As described above, if the peripheral device 40 is a home electric device that can be operated by the infrared remote control, the peripheral device 40 does not need to be provided with a home electric appliance adapter.

As described below, the peripheral device 40 is indirectly controlled by the cloud server 20 via the air conditioner 30. The peripheral device 40 and the air conditioner 30 can communicate with each other, for example, via a wireless LAN network in the house.

(Configuration of air conditioning system 100)
FIG. 2 is a functional block diagram showing a configuration of a main part of the air conditioning system 100. Hereinafter, the configuration of each member in the air conditioning system 100 will be described in more detail.

The mobile terminal 10 includes a touch panel 11, a control unit 12, a communication unit 15, a biometric sensor 16, and a storage unit 17. The touch panel 11 is a member in which (i) at least a display unit 11a that displays an image and (ii) an input unit 11b that receives a user's input (operation) are superimposed and integrated. The user can operate the air conditioner 30 by touching each button displayed on the touch panel 11 (screen of the sleep app) (see FIG. 4 described later).

However, in the mobile terminal according to one aspect of the present invention, the display unit 11a and the input unit 11b may be provided as separate members. In this case, the input unit 11b may be a hard key, for example. In this case, the user may operate the input unit 11b to make an input to the button displayed on the screen of the sleep app.

FIG. 3 is a diagram showing an example of a screen displayed on the display unit 11a before the sound sleep application is launched on the mobile terminal 10. As shown in FIG. 3, the display unit 11a displays buttons (icons) for launching various applications installed in the mobile terminal 10. In FIG. 3, button I is an icon for launching a good sleep application. The user can start the good sleep application by touching the button I on the touch panel 11.

FIG. 4 is a diagram showing an example of a screen (screen of the sleep app) displayed on the display unit 11a after the sleep app is launched in the mobile terminal 10. As shown in FIG. 4, various buttons for allowing the user to set the operation mode of the air conditioner 30 are displayed on the screen of the sound sleep application. In this way, the good sleep application provides the user with the operation mode setting screen (a screen for allowing the user to set the operation mode of the air conditioner 30).

In FIG. 4, the button J1 is a button for starting a “sleep preparation mode” described later and for setting the sleep preparation mode. This button J1 is also called a "good night preparation" button. The button J2 is a button for starting a “sleep mode” described later and setting the sleep mode. This button J2 is also called a "good night" button.

Further, the button J3 is a button for setting a set time (scheduled wake-up time) of the alarm clock. The button J4 is a button for ending the sleep preparation mode or the sleep mode on the way. This button J4 is also called a "stop" button.

The control unit 12 centrally controls each unit of the mobile terminal 10. The function of the control unit 12 may be realized by a CPU (Central Processing Unit) executing a program stored in the storage unit 17. The storage unit 17 stores various programs executed by the control unit 12 (eg, the sleep application described above) and data used by the programs.

The communication unit 15 is a communication interface for the mobile terminal 10 to communicate with an external device. The communication unit 15 can communicate with the communication unit 25 (described later) of the cloud server 20 via the communication network 90a.

The biometric sensor 16 is a sensor that acquires (detects) biometric information of the user. In the present embodiment, the case where the biological sensor 16 includes an acceleration sensor and a temperature sensor will be described as an example. The biometric sensor 16 may be a non-contact sensor that acquires biometric information without touching the user, or a contact sensor that contacts the user and acquires biometric information.

As shown in a graph (sleep curve) shown in FIG. 5 (described later), in general, when the user sleeps deeply (in the case of non-REM sleep), the possibility of hitting the roll is reduced, and thus the acceleration of the user is reduced. The change (in other words, the amount of displacement) is reduced. On the other hand, when the user sleeps lightly (in the case of REM sleep), there is a high possibility that he/she will fall over and the change in acceleration of the user will increase.

Therefore, the acceleration of the user detected by the acceleration sensor can be used as biometric information indicating the sleep depth of the user. The biometric information acquired by the biometric sensor 16 is provided to the control unit 21 (described later) of the cloud server 20. The control unit 21 can determine the sleep depth of the user based on biometric information (eg, user acceleration). Note that the control unit 21 can also generate the above-described graph (sleep curve) showing the temporal change in the sleep depth of the user based on the history of the biometric information acquired for each day.

Moreover, when the user is in the state of non-REM sleep, the body temperature of the user is lower than that in the case of REM sleep. Therefore, the body temperature of the user detected by the temperature sensor can also be used as biometric information indicating the sleep depth of the user. Note that the control unit 21 can also generate a graph (body temperature curve) showing a temporal change in the body temperature of the user during sleep, based on the history of the body temperature of the user acquired for each day.

Further, the user's pulse, blood pressure, sweat rate, and the like may be used as the biometric information. Alternatively, the content rate of a predetermined substance (eg, melatonin, growth hormone, cortisol) in the body fluid (eg, blood or saliva) of the user may be used as the biometric information. That is, the biometric sensor 16 only needs to be able to acquire biometric information in a predetermined mode. Therefore, the type of sensor included in the biosensor 16 is not particularly limited.

FIG. 5 is a diagram illustrating an example of a screen displayed on the display unit 11a according to a user's selection during execution of the sleep app on the mobile terminal 10. As shown in FIG. 5, an image IMG1 showing the above-mentioned sleep curve and body temperature curve is displayed on one screen of the sleep app. The user can easily recognize his/her daily sleep state by checking each curve of the image IMG1.

It should be noted that the image IMG1 may further include, for example, a graph showing a change over time in the amount of perspiration of the user. Further, the image IMG1 may further include a graph showing the change over time in the content rate of the predetermined substance in the body fluid of the user. This allows the user to recognize his/her daily sleep state from a multifaceted viewpoint.

Further, (i) an image IMG2 showing a set temperature of the air conditioner 30 and (ii) an image IMG3 showing a set time (scheduled wake-up time) of the alarm clock are displayed on one screen of the sleep app. Further, the images IMG2 and IMG3 include buttons (up/down buttons) for the user to change the set temperature and the set time, respectively. The scheduled wake-up time is set in advance on the sleep app by the user's operation in advance.

Then, as shown in FIG. 2 described above, the control unit 12 includes a display control unit 13 and a mode setting unit 14. The display control unit 13 controls the display of the image displayed on the display unit 11a. The mode setting unit 14 may also have the function of the display control unit 13.

The mode setting unit 14 gives the cloud server 20 a command (mode switching command) for switching the operation mode of the air conditioner 30. The mode switching command is given from the mode setting unit 14 to the air conditioning control unit 24 (described later) of the cloud server 20 via the communication units 15 and 25.

In addition, in this embodiment, the operation mode of the air conditioner 30 further includes at least two of a “sleep preparation mode” and a “sleep mode” in addition to a known operation mode (eg, an automatic operation mode). There is.

In the automatic operation mode, the air conditioner 30 operates in its own operation mode (eg, cooling operation, heating operation) based on various environmental information (eg, room temperature, outside temperature, seasonal change, change in sunlight) or A mode for automatically setting a set temperature and the like for operation may be included.

The sleep preparation mode is a mode for providing an indoor environment suitable for the user to fall asleep. The sleep mode is a mode for providing an indoor environment suitable for the user's sleep. Specific examples of the operation of the air conditioner 30 in these two modes will be described in detail later. For the sake of distinction between the sleep preparation mode and the sleep mode, the other driving modes are conveniently referred to as normal driving modes.

The cloud server 20 includes a control unit 21, a communication unit 25, and a storage unit 26. The control unit 21 centrally controls each unit of the cloud server 20. The function of the control unit 21 may be realized by the CPU executing the program stored in the storage unit 26. Since the control unit 21 is provided in the cloud server 20, it is generally provided with a high-performance information processing function as compared with the control unit 12 and the microcomputer 31 described later.

The storage unit 26 stores various programs executed by the control unit 21 (for example, the sleep program described above) and data used by the programs. The communication unit 25 is a communication interface for the cloud server 20 to communicate with an external device. The communication unit 25 can communicate with the communication unit 36 (described later) of the air conditioner 30 via the communication network 90b.

The control unit 21 also includes an air conditioning control unit 24. The air conditioning controller 24 controls the operation of the air conditioner 30. Specifically, the air conditioning control unit 24 switches the operation mode to the air conditioner 30 so as to operate the air conditioner 30 according to the operation mode of the air conditioner 30 designated by the mode switching command. Give a command. Hereinafter, the command for switching the operation mode from the air conditioning controller 24 to the air conditioner 30 will be referred to as a first command. As an example, the first command is a command to operate the air conditioner 30 in the sleep preparation mode or the sleep mode.

The air conditioner 30 includes a microcomputer (microcomputer) 31, an infrared sensor 35, and a communication unit 36. The microcomputer 31 centrally controls each unit of the air conditioner 30. The communication unit 36 is a communication interface for the air conditioner 30 to communicate with an external device. Communication between the air conditioner 30 and the peripheral device 40 is performed via the communication unit 36.

Further, the microcomputer 31 includes a peripheral device control unit 34. The peripheral device control unit 34 controls the operation of the peripheral device 40. Specifically, the peripheral device control unit 34 gives a command (hereinafter, referred to as a second command) corresponding to the above-described first command to the peripheral device 40. By giving the second command to the peripheral device 40, it is possible to cause the peripheral device 40 to perform an operation according to the operation mode (eg, sleep preparation mode) of the air conditioner 30.

The microcomputer 31 is an information processing device having a relatively simple configuration. Therefore, the information processing performance of the microcomputer 31 is generally lower than that of the control unit 21 described above.

Further, FIG. 6 is a diagram showing variations in the direction of the air blown into the room from the airflow panel of the air conditioner 30. As shown in FIG. 6, the air conditioner 30 can send the wind into the room in six wind directions 1 to 6. The wind direction 1 is the uppermost wind direction (the direction from the floor to the ceiling), and the wind direction 6 is the lowermost wind direction (the direction from the ceiling to the floor). The direction of wind direction is downward in the order of wind directions 1 to 6.

Then, as shown in FIG. 2 described above, the peripheral device 40 includes a lighting device 41, a television 42, and an aroma generator 43. The peripheral device 40 receives the second command from the peripheral device control unit 34, and operates according to the operation mode of the air conditioner 30.

As an example, the lighting device 41 is a ceiling light capable of adjusting the color and illuminance of illumination light. The television 42 is an example of an AV (Audio Visual) device that outputs at least one type of music, voice, and video designated in advance by the user. As the AV device, a radio or a notebook PC may be used instead of the television 42.

Further, the aroma generator 43 is an example of an odor generator that generates an odor (a predetermined type of aroma that the user feels comfortable) designated in advance by the user. A specific example of the operation of each member of the peripheral device 40 will be described later.

(Processing flow of the air conditioning system 100 from sleep preparation to waking up)
In the air conditioning system 100, four stages of “sleep preparation”, “sleeping”, “sleeping”, and “wake-up” are considered. FIG. 7 is a sequence diagram illustrating the flow of processing of the air conditioning system 100 from sleep preparation to waking up. The sleep preparation mode described above is a mode that considers the stage of sleep preparation. On the other hand, the above-mentioned sleep mode is a mode that takes into consideration the stages from falling asleep to getting up.

Then, FIG. 8 is an example of a time chart showing a schedule of time change of the set temperature of the air conditioner 30 (that is, the temperature inside the room) in the sleep mode (that is, from the time of falling asleep to the time of waking up). In the sleep preparation mode, temperature control that is substantially the same as in the normal operation mode (eg, automatic operation mode) is performed. Therefore, the time chart in the sleep preparation mode is omitted. The air conditioning control in the sleep preparation mode may be any one that prepares an indoor environment suitable for the user to fall asleep prior to the start of the sleep mode (start of sleep control described later).

In the present embodiment, the time chart of FIG. 8 is created by the air conditioning control unit 24. In the sleep mode, the air conditioning controller 24 supplies the microcomputer 31 with the time chart, so that the air conditioner 30 operates according to the time chart. The numerical values of temperature and time shown in the time chart of FIG. 8 are merely examples, and the present invention is not limited to these.

First, the case of the cooling operation shown in FIG. 8 will be described. The air conditioner 30 raises the set temperature by 1° C. at the start of the air conditioning control (sleep control) suitable for the user to fall asleep. The sleep onset control is an air conditioning control intended to increase the blood flow of the user's limbs and lower the core body temperature of the user. The sleep onset control is the air conditioning control at the first stage in the sleep mode.

Here, in the mobile terminal 10, it is assumed that a "good night" button (the above-mentioned button J2) for starting the sleep mode is displayed on the screen of the above-described sound sleep application. In this case, the user presses the sleep button to start sleep control. In this case, the sleep onset control start time coincides with the time when the user presses the sleep button. However, as described in Embodiment 2 below, the mobile terminal 10 can also automatically start the sleep mode.

Then, 0.5 H (30 minutes) after the start of the sleep control, the air conditioner 30 shifts to the air conditioning control (sleep control) for providing the indoor environment suitable for the user's sleep. The control during sleep is air-conditioning control intended to maintain a room temperature at which the user does not have difficulty sleeping.

In the sleep control, the air conditioner 30 raises the set temperature by 1° C. for each 0.5H. Then, the air conditioner 30 maintains the set temperature at 27° C. when the set temperature rises to 27° C. (cooling standard set temperature).

Then, at 1.5 H (1 hour and a half) before the scheduled wake-up time (set time of the alarm clock), the air conditioner 30 shifts to the air conditioning control (wake-up control) suitable for the user to wake up.

In the wake-up control, the air conditioner 30 lowers the set temperature by 1° C. for each 0.5H. Then, when the set temperature drops to 25°C, the air conditioner 30 maintains the set temperature at 25°C. The wake-up control is an air conditioning control intended to gradually raise the user's core body temperature.

Next, the case of the heating operation shown in FIG. 8 will be described. Also in the heating operation, the purpose of each of the sleep control, the sleep control, and the wake-up control is the same as in the above-described cooling operation. First, the air conditioner 30 lowers the set temperature by 1° C. at the start of the sleep control. Then, 0.5 hours after the start of the sleep onset control, the air conditioner 30 shifts to the sleep control.

In the sleep control, the air conditioner 30 lowers the set temperature by 1° C. for each 0.5H. The air conditioner 30 keeps the set temperature at 18° C. when the set temperature drops to 18° C. (heating standard set temperature). Then, at 1.5 hours before the scheduled wake-up time, the air conditioner 30 shifts to the wake-up control. In the wake-up control, the air conditioner 30 raises the set temperature by 1° C. for each 0.5H. Then, when the set temperature rises to 21°C, the air conditioner 30 keeps the set temperature at 21°C.

As described above, the time chart in FIG. 8 is set in consideration of both the sleep onset control start time (sleep mode start time) and the scheduled wakeup time. That is, the air conditioning control unit 24 generates the time chart by using both the start time of sleep control and the scheduled wakeup time. That is, the air conditioning control unit 24 operates the air conditioner 30 so as to change the temperature of the room over time with reference to the start time of sleep control and the scheduled wakeup time.

By the way, in the conventional air conditioner, based on only the time corresponding to the start of sleep of the user (for example, the time when the user presses the sleep mode button or the time when the timer off time of the air conditioner is set), It was common to change the temperature over time.

On the other hand, as described above, in the air conditioning system 100, when the sleep mode is started, the air conditioning control unit 24 further considers not only the start time of the sleep mode but also the scheduled wakeup time of the user, and the indoor temperature. Can be changed over time. Therefore, it is possible to provide the user with a more comfortable sleeping environment than before.

Next, with reference to FIG. 7 again, the flow of processing of each unit of the air conditioning system 100 at each stage from sleep preparation to rising will be described. In FIG. 7, S1 to S8 are processes during sleep preparation (sleep preparation mode). Further, S11 to S39 are processes in each stage (sleep mode) from the time of falling asleep to the time of waking up. More specifically, S11 to S17 are processes for falling asleep, S21 to S23 are processes for sleeping, and S31 to S39 are processes for waking up.

(Processing during sleep preparation)
First, S1 to S8 will be described. As an example, as illustrated in FIG. 4 described above, it is assumed that a “sleep preparation” button (the above-mentioned button J1) for starting the sleep preparation mode is displayed on the screen of the sleep application on the mobile terminal 10. ..

First, in the mobile terminal 10, the input unit 11b receives, as a user operation, the user's pressing of the good night preparation button (S1). Then, the mode setting unit 14 gives the air conditioning control unit 24 (cloud server 20) a mode switching command for switching the air conditioner 30 to the sleep preparation mode (S2).

Note that switching to the sleep preparation mode means switching from the operating mode in operation to the sleep preparation mode when the air conditioner 30 is already operating in a driving mode other than the sleep preparation mode (for example, a normal driving mode). means.

However, the present invention is not limited to this, and in response to the mode switching command, the air conditioner 30 is brought into the sleep preparation mode from the stopped state (a state in which it waits for an operation instruction from the terminal device such as the mobile terminal 10 and the remote controller). You can also

Then, upon receiving the mode switching command, the air conditioning control unit 24 gives the first command to the air conditioner 30 to operate the air conditioner 30 in the sleep preparation mode (S3). The air conditioner 30 receives the above-mentioned first command and performs air conditioning control in the sleep preparation mode (S4).

In addition, the air conditioner 30 operates the infrared sensor 35 in the sleep preparation mode to check whether or not the user is present in the bedroom. Then, the air conditioner 30 gives the detection result of the infrared sensor 35 (information indicating whether or not the user is present in the room (eg, bedroom)) to the air conditioning controller 24 (S5).

Then, the air conditioning control unit 24 changes the content of the first command according to the detection result of the infrared sensor 35. As a result, the operation of the air conditioner 30 in the sleep preparation mode can be switched depending on whether or not the user is present in the room.

For example, when the user is present in the room, the air conditioning control unit 24 operates the air conditioner 30 so as to gently change the temperature in the room as compared with the case where the user is not present. You can

As an example, in the case of cooling operation, if the temperature of the room is rapidly lowered, the user may feel cold, which may cause discomfort to the user. Therefore, when the user is present in the room, the indoor temperature is not rapidly lowered to prepare an indoor environment suitable for the user's falling asleep so that the user does not feel uncomfortable. You can

On the other hand, when the user is not present in the room, the air conditioning control unit 24 operates the air conditioner 30 so as to change the temperature in the room more rapidly than when the user is present. You can When the user is not present in the room, it is not necessary to consider the discomfort of the user. Therefore, by rapidly changing the room temperature, the indoor environment suitable for the user's falling asleep can be adjusted more quickly. be able to.

In this way, if the air conditioning control is performed according to the detection result of the infrared sensor 35 (that is, if the content of the first command is changed), it is suitable for falling asleep of the user in consideration of the presence or absence of the user in the room. The indoor environment can be adjusted. Therefore, a more comfortable sleeping environment can be provided to the user.

Further, the air conditioning control unit 24 may change the direction of the wind blown from the air conditioner 30 into the room, depending on whether or not the user is present in the room. As an example, when the user is present in the room, the air conditioning controller 24 may cause the air conditioner 30 to blow air according to the wind direction 1 in FIG. 6 described above. According to the blowing in the wind direction 1, the wind is less likely to hit the user directly than in the wind directions 2 to 6. Therefore, for example, in the case of the cooling operation, the cold felt by the user can be reduced.

On the other hand, when the user is not present in the room, the air conditioning control unit 24 may cause the air conditioner 30 to blow air in any of the wind directions 2 to 6, for example. According to the blowing in the wind directions 2 to 6, the cold air spreads more quickly throughout the room than in the wind direction 1, so that the temperature in the room can be changed more rapidly. Moreover, the bedding can be cooled more directly by blowing air in the wind directions 2 to 6. Therefore, the indoor environment suitable for the user's falling asleep can be prepared more quickly.

Further, the air conditioning control unit 24 may change the amount of air blown from the air conditioner 30 into the room (air volume) depending on whether the user is present in the room or not. As an example, the air conditioning control unit 24 may increase the air volume when the user is not present in the room, compared to when the user is present in the room.

In general, when the air volume is too large, noise during air blowing becomes large. For this reason, when the user is present in the room, it is preferable not to make the air volume excessive so that the user does not feel uncomfortable due to the noise. However, when there is no user in the room, it is not necessary to consider the influence of noise on the user. In this case, the temperature inside the room can be changed more rapidly by increasing the air volume. Therefore, the indoor environment suitable for the user's falling asleep can be prepared more quickly.

Further, when the air conditioner 30 is provided with a PCI (Plasma Cluster Ion, plasma cluster (registered trademark) ion) generator, the air conditioner 30 can send out a wind containing PCI. The air conditioning control unit 24 may change the amount of PCI contained in the wind sent out from the air conditioner 30 into the room, depending on whether the user is present in the room or not.

For example, when the user is present in the room, the amount of PCI contained in the wind may be increased as compared with the case where the user is not present in the room. Thereby, a clean air environment can be promptly provided to the user. In addition, the direction in which the user is located may be specified based on the detection result of the infrared sensor 35, and the air may be blown toward that direction.

PCI is an example of charged particles that cleans the air environment. The type of the charged particles is not limited to PCI as long as it has a function of cleaning the air environment. Therefore, the air conditioner 30 may be provided with another type of charged particle generator instead of the PCI generator.

Then, after S5, the air conditioning control unit 24 gives a command to the peripheral device control unit 34 so that the second command corresponding to the first command is supplied from the peripheral device control unit 34 to the peripheral device 40 ( S6). Specifically, the air conditioning control unit 24 creates a time chart for controlling the peripheral devices according to the progress of time according to the content of the first command, and gives the time chart to the peripheral device control unit 34. .. Then, the peripheral device control unit 34 operates the peripheral device 40 based on the time chart. That is, the peripheral device control unit 34 gives the second command corresponding to the first command to the peripheral device 40 (S7). The air conditioning control unit 24 may change the time chart according to the content of the first command according to the detection result of the infrared sensor 35.

As a result, the peripheral device 40 operates based on the second command (S8). As an example, the second command in S8 may include a command to cause the lighting device 41 to output warm-color (eg, heating) or cold-color (eg, cooling) illumination light with relatively low illuminance. .. That is, the second command may include a command for controlling the color and illuminance of illumination light so as to provide the user before falling asleep with an indoor environment suitable for falling asleep from a visual point of view. ..

Further, the second command may include a command to cause the television 42 to output a predetermined music or voice (eg, environmental sound for sleep). That is, the second command may include a command for controlling the audio output of the television 42 so as to provide the user before falling asleep with an indoor environment suitable for falling asleep from the viewpoint of hearing.

In addition, the second command includes a command that causes the aroma generator 43 to selectively generate a predetermined aroma (eg, a scent of a specific perfume, a scent effective for falling asleep) from among a plurality of types of aromas. You can be. That is, the second command may include a command for controlling the aroma generation of the aroma generator 43 so as to provide the user before falling asleep with an indoor environment suitable for falling asleep from an olfactory point of view. ..

As described above, in the sleep preparation mode, the second instruction is given from the air conditioner 30 to the peripheral device 40 to further consider the comfort of the user from the viewpoints of visual, auditory, and olfactory senses. , It is possible to provide an indoor environment suitable for falling asleep.

The peripheral device control unit 34 may acquire the detection result of the infrared sensor 35 from the air conditioning control unit 24. Then, the peripheral device control unit 34 may change the content of the second command depending on whether the user is present in the room or not. That is, the peripheral device control unit 34 may change the operation of the peripheral device depending on whether the user is present in the room or not.

For example, the peripheral device control unit 34 may turn off the lighting device 41 and the television 42 when the user is not present in the room. This is because when the user is not present in the room, it is not necessary to consider the visual and auditory comfort of the user.

The first motion command may include a command that changes the content of the second motion command. Also in this case, the operation of the peripheral device 40 can be changed depending on whether the user is present in the room or not.

(Processing when falling asleep)
Subsequently, S11 to S17 will be described. As shown in FIG. 4 described above, it is assumed that a “sleep button” (button J2 described above) for starting the sleep mode is displayed on the screen of the good sleep application.

First, in the mobile terminal 10, the input unit 11b accepts a user's operation of pressing the sleep button as a user operation (S11). Then, the mode setting unit 14 gives a mode switching command to the air conditioning control unit 24 to switch the air conditioner 30 to the sleep mode (S12).

Then, upon receiving the mode switching command from the mode setting unit 14, the air conditioning control unit 24 gives the first command to the air conditioner 30 to operate the air conditioner 30 in the sleep mode (S13). Upon receiving the first command, the air conditioner 30 starts the sleep control described above (S14).

In the sleep mode, it is preferable to reduce the illuminance of a driving lamp (not shown) indicating the driving state of the air conditioner 30 to the minimum value that can be visually recognized by the user in the dark room. Further, it is preferable that the other lamps of the air conditioner 30 are turned off. When the air conditioner 30 or the like is provided with a speaker (not shown) for voice communication, the air conditioner 30 or the like should not be uttered or the speaker should be turned off. Is preferred.

Then, the air conditioning control unit 24 gives a command to the peripheral device control unit 34 so as to supply the second command corresponding to the first command from the peripheral device control unit 34 to the peripheral device 40 (S15). When the peripheral device control unit 34 gives the second command to the peripheral device 40 (S16), the peripheral device 40 operates based on the second command (S17).

As an example, the second command in S16 may include a command to turn off lighting device 41 and television 42. Alternatively, the second command may include a command to cause the television 42 to output healing music such as a lullaby or favorite music selected by the user. By turning off the illumination light and sound or outputting music, an indoor environment suitable for sleeping of the user is provided from a visual and auditory viewpoint.

(Processing during sleep)
Next, S21 to S23 will be described. First, in the mobile terminal 10, the biometric sensor 16 (eg, acceleration sensor) acquires biometric information of the user (eg, acceleration of the user). Then, the biometric sensor 16 gives the biometric information to the control unit 21 of the cloud server 20 (S21).

As described above, when the user enters the non-REM sleep state, the acceleration of the user becomes small. Therefore, it can be considered that the non-REM sleep state of the user is maintained when a significant change in the acceleration of the user has not occurred for a predetermined time (eg, 0.5H). Therefore, the control unit 21 can confirm that the non-REM sleep state is maintained based on the biological information.

Then, the air conditioning control unit 24 updates the time chart of FIG. 8 described above, for example, every 0.25H (15 minutes) by using the current time and the above-mentioned scheduled wakeup time. Then, the air conditioning controller 24 gives the time chart to the air conditioner 30 every time the time chart is updated (S22). Thereby, the air conditioner 30 can perform air conditioning control (sleep control) according to the latest time chart (S23).

In this way, by updating the time chart during sleep, it becomes possible to more reliably maintain the indoor environment suitable for the user during sleep.

(Process when waking up)
Next, S31 to S39 will be described. First, at 1.5 hours before the scheduled wake-up time, the air conditioning control unit 24 gives a first command to the air conditioner 30 and causes the air conditioner 30 to perform wake-up control (S31).

Further, the air conditioning control unit 24 gives a command to the peripheral device control unit 34 so that the peripheral device control unit 34 supplies the second command corresponding to the first command to the peripheral device 40 (S32). Subsequently, the peripheral device control unit 34 gives the second command to the peripheral device 40 (S33), and as a result, the peripheral device 40 performs an operation based on the second command (S34).

As an example, the second command in S33 may include a command to turn on the illumination device 41 and output illumination light having a relatively high illuminance in order to promote the user's awakening when getting up. Further, the second command may include a command to turn on the television 42 and output a predetermined music or voice in order to promote the user's awakening when getting up. The second command may be a command that gradually increases the output of the illumination light, the music, or the like and maximizes the output at the scheduled wake-up time.

In addition, the second command may include a command to turn off the aroma generator 43. Alternatively, the second command may include a command to generate an aroma different from that at the time of falling asleep (for example, a scent effective for drowsiness) in order to promote the user's wake-up when waking up. ..

Then, when the scheduled wake-up time arrives, the control unit 12 operates a speaker (not shown) of the mobile terminal 10 and sounds an alarm alarm (S35). Here, it is assumed that a "wake-up" button (not shown in FIG. 4) is displayed on the screen of the above-described sound sleep application as a button for stopping the alarm.

The input unit 11b receives the user's pressing of the wake-up button as a user operation (S36). As a result, the mode setting unit 14 stops the alarm clock (S37). Further, the mode setting unit 14 gives a mode switching command to the air conditioning control unit 24, and causes the air conditioner 30 to end the operation in the sleep mode (S38).

Then, when receiving the mode switching command from the mode setting unit 14, the air conditioning control unit 24 operates the air conditioner 30 in the above-described normal operation mode (eg, automatic operation mode) (S39). This completes the air conditioning control from the time of sleep preparation to the time of waking up.

Further, as shown in FIG. 4 described above, a “stop” button (button J4 described above) for ending the sleep preparation mode or the sleep mode on the way may be further displayed on the screen of the good sleep application. When the user presses the stop button, the mode setting unit 14 gives the air conditioning control unit 24 a command to switch the air conditioner 30 to the normal operation mode even before the user presses the wake-up button.

(Effect of air conditioning system 100)
As described above, in the air conditioning system 100, when the mode setting unit 14 of the mobile terminal 10 switches the operation mode of the air conditioner 30 to a predetermined mode (eg, sleep preparation mode or sleep mode), (i) cloud The air conditioning controller 24 of the server 20 gives a first command to the air conditioner 30, and (ii) the peripheral device controller 34 of the air conditioner 30 sends a second command according to the first command to the surroundings. Provided to the device 40.

According to the configuration, the cloud server 20 directly controls (i) the air conditioner 30 to perform an operation according to the operation mode selected by the user (eg, sleep preparation mode or sleep mode). , (Ii) The peripheral device 40 can be indirectly controlled via the air conditioner 30 to cause the peripheral device 40 to perform an operation according to the operation mode.

That is, the mobile terminal 10 can give a command to the cloud server 20 and operate the cloud server 20 as a central control unit that controls the air conditioner 30 and the peripheral device 40.

By the way, as described above, the control unit provided in a general air conditioner is often a microcomputer (for example, the microcomputer 31) having relatively low processing performance. Therefore, it is not easy for the microcomputer to perform complicated control of the air conditioner itself and peripheral devices.

On the other hand, according to the air conditioning system 100, the control unit 21 (processor of the cloud server 20) having a processing performance sufficiently higher than that of the microcomputer 31 facilitates complicated control of the air conditioner 30 and the peripheral device 40. Become. Therefore, the air conditioner 30 and the peripheral device 40 can be caused to perform various operations according to the operation mode selected by the user (eg, sleep preparation mode or sleep mode), and thus a more comfortable sleeping environment than before. Can be provided to the user.

In addition, even when the user is not in the bedroom (eg, when he/she is out, in a room other than the bedroom), the portable terminal 10 causes the air conditioner 30 to operate in the sleep preparation mode via the cloud server 20. Can be operated with. Therefore, it is possible to prepare an indoor environment suitable for falling asleep by the sleep preparation mode before the user enters the bedroom.

In the present embodiment, the case where the mobile terminal 10 is included as an element of the air conditioning system 100 is illustrated, but the mobile terminal 10 is not an essential element of the air conditioning system 100. The air conditioning system according to one aspect of the present invention may include the cloud server 20, the air conditioner 30, and the peripheral device 40. And the portable terminal 10 should just be able to cooperate with the said air conditioning system. Even with this configuration, the same effect as that of the above-described air conditioning system 100 can be obtained.

Further, the mode setting unit 14 of the mobile terminal 10 preferably displays various buttons for setting the driving mode when displaying the driving mode setting screen (screen of the sleep app) on the display unit 11a. By displaying the button, the user can easily perform the operation for setting the operation mode.

[Modification]
In the first embodiment described above, an example in which one cloud server 20 is used has been described, but each function of the cloud server 20 may be realized by a plurality of servers. Then, when a plurality of servers are applied, each server may be managed by the same business operator or may be managed by different business operators. This also applies to each of the embodiments described later.

[Embodiment 2]
An embodiment of the present invention will be described below with reference to FIG. For convenience of description, members having the same functions as the members described in the above embodiment will be designated by the same reference numerals, and the description thereof will be omitted.

(Air conditioning system 200)
FIG. 9 is a functional block diagram showing the configuration of the main parts of the air conditioning system 200 of this embodiment. As shown in FIG. 9, the air conditioning system 200 is the same as the air conditioning system 100 of the first embodiment, except that a learning unit 18 (mode setting unit) is added to the control unit 12 of the mobile terminal 10. Here, in order to distinguish from the members of the first embodiment, the mobile terminal of the present embodiment is referred to as a mobile terminal 10a. Further, the control unit of the mobile terminal 10a is referred to as a control unit 12a.

In the present embodiment, for convenience of description, the learning unit 18 and the mode setting unit 14 are illustrated as separate functional units, but the mode setting unit 14 may have the function of the learning unit 18 together. .. That is, the mode setting unit 14 and the learning unit 18 may be provided as an integrated functional unit.

The learning unit 18 has a function (learning function) of automatically learning the time (operation time) when the user performs a predetermined operation (input operation) on the mobile terminal 10a. More specifically, the learning unit 18 has a function of performing statistical processing on the history of operation times and calculating (setting) the optimum value of the operation times.

The learning function of the learning unit 18 may be implemented by a known automatic learning algorithm. The daily operation time may be stored in the storage unit 17 as a learning database.

(First example of automatic learning)
Hereinafter, an example of the operation of the learning unit 18 will be described. Hereinafter, the user's operation on the mobile terminal 10a for starting the sleep preparation mode is referred to as a first operation. The first operation is, for example, an operation in which the user presses the “good night preparation” button (button J1) in FIG. 4 described above. Further, the time when the first operation is performed is referred to as the first operation time.

As an example, the learning unit 18 performs the statistical processing on the history of the first operation time for each day, so that the optimum value of the time at which the operation mode of the air conditioner 30 is switched to the sleep preparation mode (hereinafter, referred to as the first time). ) May be set.

For example, the learning unit 18 acquires the first operation time on each date before today, which is recorded in the learning database, and calculates the average value (average value A1) of all the acquired first operation times. Next, the learning unit 18 extracts only the first operation time within a fixed time (example: 0.5H) from the average value A1 from all the acquired first operation times. Next, the learning unit 18 calculates the average value (average value A2) of all the extracted first operation times. Then, the learning unit 18 sets the average value A2 as the first time and gives the first time to the mode setting unit 14.

In this case, the mode setting unit 14 can switch the operation mode of the air conditioner 30 to the sleep preparation mode at the first time set by the learning unit 18 without the user performing the first operation. Therefore, the user's first operation is unnecessary, and the convenience of the user can be improved.

The mode setting unit 14 may cause the display unit 11a to display a selection button for enabling or disabling the operation of automatically starting the sleep preparation mode at the first time described above by the user. Alternatively, the mode setting unit 14 may invalidate the operation of automatically starting the sleep preparation mode when the user presses the good night preparation button.

(Second example of automatic learning)
Another example of the operation of the learning unit 18 will be described. Hereinafter, an operation performed by the user on the mobile terminal 10a to start the sleep mode is referred to as a second operation. This second operation is, for example, an operation in which the user presses the "night button" (button J2) in Fig. 4 described above. The time when the second operation is performed is referred to as the second operation time.

The learning unit 18 sets the optimum value of the time (hereinafter, referred to as the second time) at which the operation mode of the air conditioner 30 is switched to the sleep mode by performing the statistical processing on the history of the second operation time every day. Good. Note that the example of the method for setting the second time is the same as that for the above-described first time, and thus the description thereof will be omitted.

In this case, the mode setting unit 14 can switch the operation mode of the air conditioner 30 to the sleep mode at the second time set by the learning unit 18 without the user performing the second operation. Therefore, the user's second operation is also unnecessary, and the convenience of the user can be further improved.

(Third example of automatic learning)
Further, a device for more appropriately setting the above-mentioned first time will be described. When the first operation time is earlier than the first time, the learning unit 18 increases the weight of the first operation time in the statistical processing as compared with the case where the first operation time is later than the first time. Good. The reason is as follows.

Generally, when the user performs the first operation at a time earlier than usual (the first time currently set), prepare an indoor environment suitable for falling asleep earlier than before. It is thought that they are requesting. Nevertheless, if the provision of the indoor environment suitable for falling asleep is started at the first time, there is a possibility that the user's request may not be met.

Therefore, it can be said that it is preferable to change the first time to an earlier time in order to realize the user's request. On the other hand, when the first operation time is later than the first time, even if the provision of the indoor environment suitable for falling asleep is started at the first time, there is no problem from the viewpoint of satisfying the user's request.

Therefore, for the first operation time earlier than usual, the probability of changing the first time to an earlier time can be increased by increasing the weight in statistical processing. Therefore, it is possible to provide an indoor environment suitable for falling asleep without disturbing the fluctuation of the first operation time.

As an example, changing the weight in statistical processing with respect to the first operation time may be performed as follows. For example, a first operation time that is earlier than a normal time (currently set first time) by a certain time (for example, 0.5H) is referred to as a first operation time X.

Here, when the first operation time X occurs only once, the first operation time X is not included (ignored) in the average value of the first operation times. On the other hand, when the first operation time X occurs twice or more, the first operation time X that occurs after the second operation time is included in the average of the first operation times.

On the other hand, a first operation time that is later than a certain time (for example, 0.5H) from normal is referred to as a first operation time Y. Here, the first operation time Y is not included in the average value of the first operation time until the first operation time Y occurs four times or more. If the above calculation method is adopted, the first operation time X has a greater weight in statistical processing than the first operation time Y.

(Supplementary information)
Note that it is not always necessary for the learning unit 18 to perform learning (statistical processing) for some operation times. An example thereof will be described below. Hereinafter, an operation performed by the user on the mobile terminal 10a for ending the sleep mode is referred to as a third operation. The third operation is, for example, an operation in which the user presses the "wake-up button" described above. Moreover, the time when the third operation is performed is referred to as a third operation time.

It is not necessary for the learning unit 18 to perform learning for the third operation time. This is because the wake-up time (the time when the user stops the wake-up alarm) should be arbitrarily decided by the user. That is, it is not necessary to unintentionally wake up the user at the time automatically set by learning.

[Embodiment 3]
Hereinafter, two examples of variations of the operations of the control unit 21 and the learning unit 18 will be described.

(First example)
By the way, as described above, the control unit 21 can confirm the sleep state of the user based on the biometric information. Therefore, a function of calculating (estimating) the sleep onset time and the wakeup time of the user based on the biometric information may be added to the control unit 21. Hereinafter, the user's sleep onset time and wakeup time calculated by the control unit 21 will be referred to as the sleep onset estimated time and the wakeup estimated time.

The learning unit 18 may further perform learning for the sleep onset estimated time and the wakeup estimated time. As a result, the air conditioning control according to the actual sleep state of the user becomes possible, so that a more comfortable sleeping environment for the user can be provided.

(Second example)
Also, consider a case where a plurality of users (eg, a couple) sleep together in a bedroom. Generally, since there are individual differences in the air-conditioning environment that people feel comfortable with, it is preferable to consider such individual differences in order to provide a comfortable sleeping environment for a plurality of users.

Therefore, the function of evaluating the sleep state of each user may be further added to the control unit 21, and the learning unit 18 may further perform learning based on the evaluation result. As an example, consider a case where the evaluation result shows that the husband feels sleepy depending on the height of the room temperature.

For example, the learning unit 18 uses the learning result based on the evaluation result to specify the timing of changing the wind direction of the air conditioner 30 so that the cool air is directed only to the husband while the plurality of users are sleeping. You can Note that the sleep difficulty of the husband may be evaluated at any time based on the fact that the biosensor detects frequent rolling over, not based on the evaluation result by learning. As a result, more comfortable air conditioning control can be provided for both the couple. As described above, by setting the pattern of the air conditioning control considering the individual difference of each user using the learning result, it is possible to provide a comfortable sleeping environment for a plurality of users.

[Example of software implementation]
The control blocks of the air conditioning system 100/200 (particularly the control unit 12/12a, the control unit 21, and the microcomputer 31) may be realized by a logic circuit (hardware) formed in an integrated circuit (IC chip) or the like. , May be realized by software using a CPU (Central Processing Unit).

In the latter case, the air conditioning system 100/200 includes a CPU (Execute Only) that executes the instructions of a program that is software that realizes each function, a ROM (Read Only Memory) in which the program and various data are recorded so that they can be read by a computer (or a CPU). ) Or a storage device (these are referred to as a “recording medium”), a RAM (Random Access Memory) for expanding the program, and the like. Then, the computer (or CPU) reads the program from the recording medium and executes the program to achieve the object of the present invention. As the recording medium, a “non-transitory tangible medium”, for example, a tape, a disk, a card, a semiconductor memory, a programmable logic circuit, or the like can be used. The program may be supplied to the computer via any transmission medium (communication network, broadcast wave, etc.) capable of transmitting the program. The present invention can also be realized in the form of a data signal embedded in a carrier wave, in which the above program is embodied by electronic transmission.

[Summary]
An air conditioning system (100) according to Aspect 1 of the present invention includes an air conditioner (30) for air conditioning a room (eg, bedroom), a peripheral device (40) provided in the room, and a terminal device (portable terminal). 10) and a server device (cloud server 20) connected to the air conditioner and the terminal device via a communication network (90), wherein the server device is the air An air conditioning control unit (24) for controlling the air conditioner is provided, the air conditioner is provided with a peripheral device control unit (34) for controlling the peripheral device, and the terminal device is provided for the air conditioner. A mode setting unit (14) for switching the operation mode is provided, and the operation mode includes a sleep preparation mode that is a mode for providing an indoor environment suitable for the user to fall asleep, and the mode setting unit, When the operation mode is switched to the sleep preparation mode, the air conditioning control unit gives the air conditioner a first command to operate the air conditioner in the sleep preparation mode, and the peripheral device control unit A second command corresponding to the first command is given to the peripheral device.

According to the above configuration, when the mode setting unit of the terminal device switches the operation mode of the air conditioner to the sleep preparation mode, the air conditioning controller of the server device gives the first command to the air conditioner. In addition, the peripheral device controller of the air conditioner gives the peripheral device a second command in response to the first command.

By the way, as described above, the control unit provided in a general air conditioner is often a microcomputer. On the other hand, the control unit (processor) of the server device has relatively higher processing performance than the microcomputer.

Therefore, according to the above configuration, the server device causes the control unit having higher processing performance than the microcomputer to directly control the air conditioner to perform an operation according to the sleep preparation mode. (Ii) The peripheral device can be indirectly controlled via the air conditioner, and the peripheral device can be caused to perform an operation according to the sleep preparation mode.

That is, the control unit of the server device facilitates complicated control of the air conditioner and peripheral devices. For this reason, the air conditioner and the peripheral devices can be caused to perform various operations according to the sleep preparation mode, so that it is possible to provide the user with a more comfortable sleeping environment than before.

Even when the user is not in the room (for example, when he/she is out, in a room other than the bedroom), the terminal device operates the air conditioner in the sleep preparation mode via the server device. Can be made. Therefore, it is possible to prepare an indoor environment suitable for falling asleep by the sleep preparation mode before the user enters the bedroom.

An air conditioning system according to aspect 2 of the present invention is the air conditioner according to aspect 1, wherein the air conditioner further includes a sensor (infrared sensor 35) that detects that the user is present in the room. In the preparation mode, the air conditioning control unit may change the content of the first command according to the detection result of the sensor.

According to the above configuration, the operation of the air conditioner in the sleep preparation mode can be changed depending on whether the user is present inside the room or not. For example, when the user does not exist in the room, the temperature inside the room can be changed more rapidly than when the user exists.

Further, since the peripheral device control unit gives the peripheral device a second operation command according to the first operation command, it is possible to cause the peripheral device to perform an operation according to the change in the content of the first operation command. Therefore, it is possible to provide the user with a more comfortable sleeping environment.

In this way, the environment for falling asleep can be prepared in consideration of the presence or absence of the user, so that a more comfortable sleeping environment can be provided to the user.

The first motion command may include a command that changes the content of the second motion command. Also in this case, the operation of the peripheral device can be changed depending on whether the user is present in the room or not.

In the air conditioning system according to Aspect 3 of the present invention, in the Aspect 1 or 2, the operation mode further includes a sleep mode that is a mode for providing an indoor environment suitable for the sleep of the user. When the setting unit switches the operation mode to the sleep mode, the air conditioning control unit uses the start time of the sleep mode and a preset wakeup time of the user as a reference, and the air conditioner in the sleep mode is set. The room temperature may be changed.

By the way, as described above, in the conventional air conditioner, only at the time corresponding to the start of sleep of the user (for example, the time when the user presses the sleep mode button or the time when the timer off time of the air conditioner is set). Based on this, it has been common to change the temperature of the room over time. On the other hand, according to the above configuration, when the sleep mode is enabled, the temperature in the room can be changed over time by further considering not only the sleep mode start time but also the scheduled wakeup time of the user. It is possible to provide the user with a more comfortable sleeping environment.

The air conditioning system according to Aspect 4 of the present invention is the air conditioner system according to any one of Aspects 1 to 3, wherein an input operation to the terminal device by the user to start the sleep preparation mode is performed as a first operation. The setting unit (learning unit 18) sets the first time, which is the time when the operation mode is switched to the sleep preparation mode, by performing the statistical processing on the first operation time, which is the time when the first operation is performed. You may.

According to the above configuration, the first time is set by performing statistical processing on the history of the first operation time for each day (in other words, automatic learning of the first operation time) in the mode setting unit. To be done. Therefore, it is possible to automatically switch to the sleep preparation mode without the user performing the first operation. Therefore, it is possible to improve the convenience of the user.

In the air conditioning system according to the fifth aspect of the present invention, in the fourth aspect, when the first operation time is earlier than the first time, the mode setting unit causes the first operation time to be earlier than the first time. The weight of the first operation time in the statistical processing may be increased as compared with the case of being late.

As described above, in general, when the user performs the first operation at a time earlier than usual, it is requested to prepare an indoor environment suitable for falling asleep earlier than before. it is conceivable that. Nevertheless, if the provision of the indoor environment suitable for falling asleep is started at the first time, there is a possibility that the user's request may not be met. Therefore, it can be said that it is preferable to change the first time to an earlier time in order to realize the user's request. On the other hand, when the first operation time is later than the first time, even if the provision of the indoor environment suitable for falling asleep is started at the first time, there is no problem from the viewpoint of satisfying the user's request.

Therefore, according to the above configuration, the probability of changing the first time to an earlier time can be increased by increasing the statistical processing weight for the first operation time earlier than usual. Therefore, it is possible to provide an indoor environment suitable for falling asleep without disturbing the fluctuation of the first operation time.

In the air conditioning system according to Aspect 6 of the present invention, in any one of Aspects 1 to 5, the operation mode further includes a sleep mode that is a mode for providing an indoor environment suitable for sleeping of the user. Therefore, with the input operation of the user to the terminal device for starting the sleep mode as the second operation, the mode setting unit performs statistics on the second operation time which is the time when the second operation is performed. The second time, which is the time when the operation mode is switched to the sleep mode, may be set by performing the process.

According to the above configuration, it is possible to automatically switch to the sleep mode without the user performing the second operation. Therefore, the convenience of the user can be further improved.

In the terminal device according to aspect 7 of the present invention, the server device causes an air conditioner that performs air conditioning in the room to perform an operation according to a predetermined operation mode, and the air conditioner is a peripheral area provided in the room. A terminal device that cooperates with an air conditioning system configured to control the operation of the device, and a display unit (11a) that displays at least an image, and a mode setting unit that sets the operation mode of the air conditioner, Each operation of the air conditioner and the peripheral device is provided with a communication unit (15) that communicates with the server device, and the operation mode of the air conditioner provides an indoor environment suitable for a user to fall asleep. Includes a sleep preparation mode which is a mode for setting the driving mode, and the mode setting unit displays the driving mode setting screen (eg, the screen of the sleep app shown in FIG. 4) for the user to set the driving mode. When displaying on the display unit, a button (button J1) for setting the sleep preparation mode is displayed.

According to the above configuration, the same effect as that of the air conditioning system according to one aspect of the present invention is obtained. Further, since the button is displayed on the display unit, the user can easily perform the operation for setting the sleep preparation mode.

[Appendix]
The present invention is not limited to the above-described embodiments, but various modifications can be made within the scope of the claims, and embodiments obtained by appropriately combining the technical means disclosed in the different embodiments Is also included in the technical scope of the present invention. Furthermore, new technical features can be formed by combining the technical means disclosed in each of the embodiments.

10, 10a Mobile terminal (terminal device)
11a display unit 14 mode setting unit 15 communication unit 18 learning unit (mode setting unit)
35 Infrared sensor (sensor)
20 Cloud server (server device)
24 Air Conditioning Control Section 30 Air Conditioner 34 Peripheral Equipment Control Section 40 Peripheral Equipment 90, 90a, 90b Communication Network 100, 200 Air Conditioning System J1 Button

Claims (8)

An air conditioner for air conditioning the room,
Peripheral equipment provided in the room,
A terminal device,
An air conditioning system comprising a server device connected to the air conditioner and the terminal device via a communication network,
The server device includes an air conditioning control unit that controls the air conditioner,
The air conditioner includes a peripheral device control unit that controls the peripheral device,
The terminal device includes a mode setting unit that switches the operation mode of the air conditioner,
The driving mode includes a sleep preparation mode which is a mode for providing an indoor environment suitable for the user to fall asleep,
When the mode setting unit switches the driving mode to the sleep preparation mode,
The air conditioning controller gives a first command to the air conditioner to operate the air conditioner in the sleep preparation mode,
The peripheral device control section gives a second command corresponding to the first command to the peripheral device ,
An input operation of the user with respect to the terminal device for starting the sleep preparation mode is a first operation,
The mode setting unit sets a first time, which is a time at which the operation mode is switched to the sleep preparation mode, by performing a statistical process on a first operation time that is a time at which the first operation is performed. A characteristic air conditioning system. An air conditioner for air conditioning the room,
Peripheral equipment provided in the room,
A terminal device,
An air conditioning system comprising a server device connected to the air conditioner and the terminal device via a communication network,
The server device includes an air conditioning control unit that controls the air conditioner,
The air conditioner includes a peripheral device control unit that controls the peripheral device,
The terminal device includes a mode setting unit that switches the operation mode of the air conditioner,
The driving mode includes a sleep preparation mode which is a mode for providing an indoor environment suitable for the user to fall asleep,
When the mode setting unit switches the driving mode to the sleep preparation mode,
The air conditioning controller gives a first command to the air conditioner to operate the air conditioner in the sleep preparation mode,
The peripheral device control section gives a second command corresponding to the first command to the peripheral device ,
The driving mode further includes a sleep mode which is a mode for providing an indoor environment suitable for sleeping of the user,
An input operation of the user to the terminal device for starting the sleep mode is a second operation,
The mode setting unit sets a second time, which is a time at which the driving mode is switched to the sleep mode, by performing a statistical process on a second operation time that is a time at which the second operation is performed. Air conditioning system to be. The air conditioner further includes a sensor that detects that the user is present in the room,
In the sleep preparation mode,
The air conditioning system according to claim 1 or 2 , wherein the air conditioning control unit changes the content of the first command according to the detection result of the sensor. The driving mode further includes a sleep mode which is a mode for providing an indoor environment suitable for sleeping of the user,
When the mode setting unit switches the driving mode to the sleep mode,
The air conditioning control unit, and the start time of the sleep mode, based on the wakeup schedule time of the user which is set in advance, from claim 1, characterized in that changing the temperature of the chamber in the sleep mode 3 The air conditioning system according to any one of 1 . An input operation of the user with respect to the terminal device to start the sleep preparation mode is a first operation,
The mode setting unit sets a first time, which is a time at which the operation mode is switched to the sleep preparation mode, by performing a statistical process on a first operation time that is a time at which the first operation is performed. The air-conditioning system according to any one of claims 2 to 4 , which is characterized. When the first operation time is earlier than the first time,
The said mode setting part makes the weight in the statistical processing of the said 1st operation time large compared with the case where the said 1st operation time is later than the said 1st time, The claim 1 or 5 characterized by the above-mentioned. Air conditioning system. The server device is configured to cause an air conditioner for air conditioning in the room to perform an operation according to a predetermined operation mode, and the air conditioner is configured to control the operation of peripheral devices provided in the room. A terminal device that cooperates with an air conditioning system,
At least a display unit that displays an image,
A mode setting unit that sets the operation mode of the air conditioner,
A communication unit that communicates with the server device,
The operation mode of the air conditioner includes a sleep preparation mode that is a mode for setting each operation of the air conditioner and the peripheral devices so as to provide an indoor environment suitable for the user to fall asleep,
The mode setting unit, when displaying a driving mode setting screen for the user to set the driving mode on the display unit, displays a button for setting the sleep preparation mode ,
An input operation of the user with respect to the terminal device to start the sleep preparation mode is a first operation,
The mode setting unit sets a first time, which is a time at which the operation mode is switched to the sleep preparation mode, by performing a statistical process on a first operation time that is a time at which the first operation is performed. Characteristic terminal device. The server device is configured to cause an air conditioner for air conditioning in the room to perform an operation according to a predetermined operation mode, and the air conditioner is configured to control the operation of peripheral devices provided in the room. A terminal device that cooperates with an air conditioning system,
At least a display unit that displays an image,
A mode setting unit that sets the operation mode of the air conditioner,
A communication unit that communicates with the server device,
The operation mode of the air conditioner includes a sleep preparation mode that is a mode for setting each operation of the air conditioner and the peripheral devices so as to provide an indoor environment suitable for the user to fall asleep,
The mode setting unit, when displaying a driving mode setting screen for the user to set the driving mode on the display unit, displays a button for setting the sleep preparation mode ,
The driving mode further includes a sleep mode which is a mode for providing an indoor environment suitable for sleeping of the user,
An input operation of the user to the terminal device for starting the sleep mode is a second operation,
The mode setting unit sets a second time, which is a time at which the driving mode is switched to the sleep mode, by performing a statistical process on a second operation time, which is a time at which the second operation is performed. And the terminal device.

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