JP2017046281A - Controller, electric apparatus, control system, and control method for control system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To improve convenience of remote control of an electric apparatus.SOLUTION: A controller for transmitting a control signal to an electric apparatus comprises: a memory for storing a setting state of the electric apparatus; and a processor. The processor, when a remotely controlled instruction to the electric apparatus has been received, acquires a setting state of the electric apparatus to store the setting state in the memory; transmits a control signal based on the received instruction to the electric apparatus and starts a timer; and, when the timer has expired, transmits a control signal for changing the electric apparatus into a stored state to the electric apparatus.SELECTED DRAWING: Figure 6

Description

  The present disclosure relates to a controller for transmitting a control signal to an electric device and a control system including the controller.

  2. Description of the Related Art Conventionally, a technique for remotely controlling a controlled device such as an air conditioner by wireless communication using a mobile terminal such as a smartphone has been proposed. For example, in Japanese Patent Application Laid-Open No. 2003-284162 (Patent Document 1), depending on whether or not a wireless communication connection between the controlled device and the portable terminal is established, the controlled device itself is It is disclosed that the absence of a control device is recognized, and a transition to an answering mode set in advance by itself is made.

JP 2003-284162 A

  However, in the technique described in Patent Document 1, it is only assumed that the controlled device is shifted to the answering machine mode when the user is absent. On the other hand, even when the mobile terminal is located in a place where the mobile terminal cannot be directly wirelessly communicated with an in-home device such as an air conditioner, such as when the user of the mobile terminal is away from home, the user's home is not always absent. Even when the user's home is not at home or when the user's home is out, there is a case where it is desired to maintain the home state by operating the home electrical device.

  As described above, there are cases where it is desired to perform control for changing the setting of an electric device in the house using a portable terminal from outside the house, and there are cases where it is desired to maintain the setting of the electric device in the house.

  The present disclosure has been conceived in view of such circumstances, and an object thereof is to improve the convenience of remote control of an electric device.

  According to a certain aspect, a controller for transmitting a control signal to an electric device includes a memory for storing a setting state of the electric device and a processor, and the processor receives an instruction to the electric device by remote control In addition, the setting state of the electric device is acquired, the setting state is stored in the memory, the control signal based on the received instruction is transmitted to the electric device, the timer is started, and the electric device is stored when the timer expires. There is provided a controller that transmits a control signal for changing to a state that has been performed to an electrical device.

  According to another aspect, there is provided an electrical device that receives a control signal by remote control, and includes a memory that stores a setting state of the electrical device, and an electrical device processor, wherein the electrical device processor instructs the electrical device by remote control. Is stored in the memory, the setting of the electrical device is changed based on the received instruction, the timer is started, and the electrical device is saved when the timer expires An electrical device is provided that changes to

  According to another aspect, a control system including a server, a controller for transmitting a control signal to the electric device, and the electric device, wherein the controller receives a setting instruction for the electric device from the server. , Acquire the setting status of the electrical device, save the acquired setting status, send a control signal to change the setting of the electrical device based on the received setting instruction for the electrical device, start the timer, expire the timer Accordingly, a control system is provided that is configured to transmit a control signal for changing the electrical device to the stored state to the electrical device.

  According to another aspect, a control system comprising an electrical device and a controller for transmitting a control signal to the electrical device, wherein the controller remotely receives a setting instruction for the electrical device by remote control. When the control signal including the control property is transmitted to the electric device, the electric device stores the setting state of the electric device when the received control signal includes the remote control property, and the electric device is based on the received control signal. A control system is provided that is configured to change the setting of the electronic device, start a timer, and change the electrical device to the saved setting state upon expiration of the timer.

  According to another aspect, a method for controlling a controller for transmitting a control signal to an electric device, the step of receiving an instruction for the electric device, and the step of determining whether the instruction is by remote control; When the instruction is by remote control, a step of acquiring the setting state of the electric device, a step of storing the acquired setting state in a memory, and a control signal to the electric device based on the received instruction There is provided a control method including a step of transmitting, a step of starting a timer, and a step of transmitting a control signal for setting the electrical device to a stored state when the timer expires.

  According to another aspect, a method for controlling an electrical device that receives a control signal by remote control, the electrical device receiving an instruction to the electrical device by remote control, and a step of saving a setting state of the electrical device A control method comprising: changing the setting of the electrical device based on the received instruction; starting a timer; and changing the electrical device to a stored state when the timer expires.

  Preferably, the method further includes the steps of receiving an instruction to extend the timer and extending the timer before the timer expires.

  ADVANTAGE OF THE INVENTION According to this invention, the convenience of remote control of an electric equipment can be improved.

It is a figure which shows the specific example of a structure of 1st Embodiment of a control system. It is a figure which shows an example of the hardware constitutions of a HEMS (Home Energy Management System) controller. It is a figure which shows schematically an example of the control structure of a HEMS controller. It is a block diagram which shows an example of the outline of a server apparatus structure. It is a block diagram which shows an example of the outline of an apparatus structure of an electric equipment. It is a figure which shows an example of the outline | summary of operation | movement in the control system of 1st Embodiment. It is a figure which shows an example of the outline | summary of operation | movement in the control system of 2nd Embodiment. It is a flowchart of the process in 3rd Embodiment. It is a figure which shows an example of the outline | summary of operation | movement in the control system of 4th Embodiment. It is a figure which shows an example of the outline | summary of operation | movement in the control system of 5th Embodiment. It is a flowchart of the process in 6th Embodiment. It is a figure which shows an example of the outline | summary of operation | movement in the control system of 7th Embodiment. It is a figure which shows an example of the outline | summary of operation | movement in the control system of 8th Embodiment.

  In the control system according to the embodiment of the present invention, the controller (HEMS controller 100 described later) receives an instruction to the electric device (electric device 200 described later) by remote control. The controller that has received the instruction acquires and stores the setting state of the electric device for the electric device. Then, the controller transmits an instruction for setting the received instruction to the electric device to the electric device, and an instruction for returning the electric device to the setting state stored after a predetermined time has elapsed. Send to device.

  In the control system according to the embodiment of the present invention, the controller (HEMS controller 100 described later) receives an instruction to the electric device (electric device 200 described later) by remote control. The controller that has received the instruction transmits to the electric device an instruction for setting the received instruction state to the electric device. The electrical device that has received the instruction by remote control stores the setting state. And the said electric equipment changes to the setting state based on the instruction | indication which received the state, and returns to the setting state preserve | saved after progress for a fixed time.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. In the following description, the same parts are denoted by the same reference numerals. Their names and functions are also the same. Therefore, detailed description thereof will not be repeated.

<1. System configuration>
FIG. 1 is a diagram illustrating a specific example of the configuration of the first embodiment of the control system. Referring to FIG. 1, the control system is a system for controlling electric device 200. The control system includes a server 300, a HEMS controller 100, and a broadband router 150. The HEMS controller 100 and the broadband router 150 relay communication between the electrical device 200 and the server 300 via a public line such as the Internet. More specifically, the HEMS controller 100 is connected to the Internet via the broadband router 150 and communicates with the server 300 via the Internet. In the following description, the communication (connection) of the HEMS controller 100 with the server 300 via the broadband router 150 is simply referred to as “the HEMS controller 100 communicates (connection) with the server 300”. In addition, a public line such as the Internet is sometimes simply referred to as the Internet.

  The electric device 200 is, for example, an air conditioner (or a lighting device or a water heater) in a home or office. In FIG. 1, only one electrical device 200 is shown, but a plurality of (plural types) electrical devices 200 may exist in the control system according to the first embodiment.

  The server 300 may be composed of devices located at a plurality of bases that share and cooperate with each other, which will be described later, or may be composed of devices located at one base. The server 300 may be composed of a single device or may be composed of a plurality of devices. The server 300 is constituted by a general computer, for example.

  Server 300 accepts access from portable terminal 400 via the Internet. The portable terminal 400 is, for example, a smartphone or a tablet terminal. The portable terminal 400 includes a touch panel 401 that is an example of an input device and / or a display device.

  The HEMS controller 100 can communicate with one or more electric devices 200. The HEMS controller 100 and the electric device 200 are each connected to the broadband router 150 and constitute the same subnet (network segment). The broadband router 150 has at least a connection function by a wired LAN (Local Area Network), and is connected to the HEMS controller 100 by a wired LAN. Preferably, the broadband router 150 further includes a wireless LAN function, and is connected to one or more electric devices 200 via a wireless LAN (or wired LAN). The HEMS controller 100 can be connected to one or more electric devices 200 (via the broadband router 150). The HEMS controller 100 can be connected to the Internet (via the broadband router 150) and communicates with the server 300 via the Internet.

<2. Configuration of HEMS controller>
FIG. 2 is a diagram illustrating an example of a hardware configuration of the HEMS controller 100. With reference to FIG. 2, the HEMS controller 100 includes a CPU (Central Processing Unit) 10 for controlling the HEMS controller 100 and a storage device 13. As an example, the storage device 13 includes a memory 11 and a RAM (Random Access Memory) 12. The memory 11 is constituted by a flash memory, for example, and stores a program executed by the CPU 10. The RAM 12 stores various types of data such as electrical device status information, which will be described later, and serves as a work area when the CPU 10 executes the program.

  The HEMS controller 100 may include an LED (Light Emitting Diode) 14 as an output unit and an operation unit 15 as an input unit. The operation unit 15 is, for example, a hardware button such as a switch and / or a software button displayed on the display.

  Further, the HEMS controller 100 includes a communication unit 16 for communicating with the electric device 200 and the broadband router 150 via a wireless LAN (or wired LAN). The communication unit 16 is realized by a communication interface such as a LAN card, for example.

  The apparatus configuration of the HEMS controller 100 is not limited to the configuration of FIG. For example, the HEMS controller 100 is configured such that a portion for communicating with the electric device 200 and other portions are separated from each other, and these portions communicate using a communication circuit such as a UART (Universal Asynchronous Receiver Transmitter). It may be embodied by being connected as possible.

  FIG. 3 is a diagram schematically illustrating an example of a control configuration of the HEMS controller 100. The control configuration of FIG. 3 is mainly realized by the CPU 10 that reads and executes a program stored in the storage device 13. However, a part of the configuration shown in FIG. 3 may be realized by other components in the HEMS controller 100.

  Referring to FIG. 3, the control configuration of HEMS controller 100 is roughly configured by server communication unit 110 for controlling communication with server 300, ECHONET Lite (registered trademark) node management unit 111, and ECHONET Lite. And a communication unit 112 for controlling communication with the node (electric device 200).

  The ECHONET Lite node management unit 111 monitors the state of the “state change announcement property” on each instance and the state of the “server notification property” specified from the server 300.

  The “state change announcement property” is a property notified from the device object side when there is a change. The contents of the property are defined in the ECHONET Lite standard. The “state change announcement property” is defined for each instance in the ECHONET Lite standard. When a new instance is detected, the ECHONET Lite node management unit 111 acquires a state change announcement property map (EPC = 0x9D) defined in the ECHONET Lite standard and creates a list of state change announcement properties.

  “Server notification property” refers to a property to be notified to the server 300. The ECHONET Lite node management unit 111 creates a list of “server notification properties” specified by the server 300. The initial value of “Server Notification Property” is empty.

  When the ECHONET Lite node management unit 111 receives an INF notification about the property of the state change announcement property from the ECHONET Lite node, the ECHONET Lite node management unit 111 notifies the server communication unit 110 of the notification. In addition, the ECHONET Lite node management unit 111 holds the latest value of the notified property.

  The ECHONET Lite node management unit 111 acquires a property (monitoring property) derived as a union of the state change announcement property and the server notification property. When the ECHONET Lite node management unit 111 detects that the value of the monitoring property has changed, the ECHONET Lite node management unit 111 notifies the server communication unit 110 of the change. This notification means that the state change announcement property or the server notification property has changed. Further, the notification includes information (1 byte) indicating whether or not the server notification property is included.

  When the server communication unit 110 receives a notification from the ECHONET Lite node management unit 111, the server communication unit 110 determines whether or not a server notification property is included in the notified property. If the server notification property is included, the server 300 notifies the server 300 of the received notification that is included in the server notification property.

  When the ECHONET Lite node management unit 111 detects either (1) or (2) below, the ECHONET Lite node management unit 111 transmits an “INF notification of an individual ECHONET Lite instance” to all authenticated transmission source clients. This is not a response to the command but a notification that the ECHONET Lite node management unit 111 executes irregularly.

(1) The state change announcement (INF) has been received. (2) The monitoring property value of the ECHONET Lite instance has changed. The ECHONET Lite node management unit 111 has detected either (1) or (2). In this case, the received property is notified to all authenticated transmission source clients as “notification ECHONET Lite message (ESV = 0 × 73)”.

  The property of “individual ECHONET Lite instance INF notification” includes a combination of what should be notified to the server and what should not be notified, but the server communication unit 110 includes the above server notification property. Whether or not to notify the server 300 can be determined based on the value of the information (1 byte) indicating the above.

  Upon receiving the “server notification property setting command” request, the ECHONET Lite node management unit 111 sets the server notification property inside the ECHONET Lite node management unit 111. The server 300 can specify an instance to be set, and can further specify properties to be notified to the server 300.

  The HEMS controller 100 distinguishes whether or not the received setting command is a remote control. For example, if the control is performed from the portable terminal 400 via the Internet, it is determined that the control is remote control. In addition, the setting command message received by the HEMS controller 100 may include a property (for example, 0x93) or a flag indicating remote control. Further, the HEMS controller 100 distinguishes whether or not the setting command is a remote control, and transmits the setting command to the electric device 200. For example, a command indicating remote control includes a property (for example, 0x93) indicating remote control.

<3. Server configuration>
FIG. 4 is a block diagram illustrating an example of a schematic configuration of the server 300. Referring to FIG. 4, server 300 includes a CPU 30 for controlling the entire server 300, a memory 34, and a communication unit 35 for performing communication via the Internet. For example, the memory 34 includes a ROM 31, a RAM 32, and an HDD (Hard Disk Drive) 33. The ROM 31 stores a program executed by the CPU 30. The RAM 32 serves as a work area when the CPU 30 executes the program, and stores calculated values. The HDD 33 is an example of a secondary storage device.

  As described above, the server 300 may be configured by a general computer. For this reason, FIG. 4 shows a schematic configuration of a general computer. The configuration of the server 300 is not limited to the configuration of FIG. For example, the server 300 may further include an operation unit and a display for receiving a user operation input. Further, as described above, when the server 300 includes a plurality of devices, each of the plurality of devices may further include a communication device for communicating with each other.

  The setting command transmitted from the server 300 may include a property (for example, 0x93) or a flag indicating remote control. This makes it easy for the HEMS controller 100 and the electric device 200 to distinguish whether the received setting command is based on remote control.

<4. Configuration of electrical equipment>
FIG. 5 is a block diagram illustrating an example of a schematic configuration of the electric device 200. Referring to FIG. 5, electric device 200 includes a CPU 20 for controlling the entire electric device 200, a memory 24, and a communication unit 25 for communicating with HEMS controller 100. As an example, the memory 24 includes a ROM 21, a RAM 22, and a flash memory 23. The ROM 21 stores a program executed by the CPU 20. The RAM 22 serves as a work area when the CPU 20 executes the program, and stores calculated values. The HDD 23 is an example of a secondary storage device.

  The electric device 200 further includes an operation unit 26. The operation unit 26 is an operating part for exhibiting a unique function of the electric device 200. As an example, when the electric device 200 is an air conditioner, the operation unit 26 includes elements for generating conditioned air, such as a fan and a compressor. As another example, if the electrical device 200 is a television, the operation unit 26 includes elements for outputting content, such as a receiver and a display for television signals.

  Electric device 200 further includes an operation unit 27. The operation unit 27 is, for example, a hardware button such as a switch and / or a software button displayed on the display. The CPU 20 receives an input of a signal corresponding to an operation on the operation unit 27. The operation unit 27 also includes a remote controller that directly transmits a control signal to the electric device 200 using infrared rays or the like. In the control system, control via the Internet from the portable terminal 400 and direct control from the operation unit 27 (remote controller) are referred to separately.

[First Embodiment]
The control system according to the first embodiment is used to remotely control an electric device 200 such as a home or office air conditioner using a portable terminal 400. The user of the mobile terminal 400 activates a remote operation application on the mobile terminal 400 and causes the touch panel 401 to display an operation image. When the user performs a touch operation on the touch panel 401 displaying the image, the portable terminal 400 outputs a control instruction to the electric device 200.

  In the control system, a control instruction transmitted from the portable terminal 400 is transmitted to the HEMS controller 100 via the server 300. Here, an outline of the operation of each element in the control system will be schematically described.

  FIG. 6 is a diagram illustrating an example of an outline of operation in the control system when an instruction from the mobile terminal 400 is transmitted. FIG. 6 shows an example of a signal flow between elements in the control system.

  Referring to FIG. 6, a control instruction (setting instruction) transmitted from portable terminal 400 is transmitted to HEMS controller 100 via server 300 (S <b> 2). In response to the instruction from the portable terminal 400, the HEMS controller 100 acquires the setting state of the electric device 200 (S3). As an example of the operation of acquiring the setting state, the HEMS controller 100 transmits a setting state acquisition signal (Get) to the electric device 200 to inquire about the setting state (S3-1), and a response (Get_Res) from the electric device 200. Is received (step S3-2). As another example, the HEMS controller 100 receives a state change announcement notification (INF) from the electrical device 200. The state change announcement notification (INF) is a notification transmitted when the electric device 200 has changed in the state of the electric device 200.

  The set state of the electric device 200 includes ON / OFF of the electric device 200, a set operation amount (temperature, humidity, illuminance, etc.), and the like.

  In the control system according to the first embodiment, when the HEMS controller 100 receives a setting state response from the electric device 200, the processor (CPU) of the HEMS controller 100 stores the setting state (M) in the memory 11 (S4). .

  The HEMS controller 100 performs setting (C) based on an instruction from the portable terminal 400 for the electric device 200 (S5). The HEMS controller 100 outputs a setting signal (SetC) for setting (C) (S5-1). When the electric device 200 receives the signal, the electric device 200 returns a signal (SetC_Res) indicating that the signal is received to the HEMS controller 100 (S5-2).

  The HEMS controller 100 operates the timer for a certain period of time after setting (C) based on the instruction from the portable terminal 400 to the electric device 200 (S6).

  After a predetermined time has elapsed, the HEMS controller 100 returns the electric device 200 to the stored setting state (M) (S7). The HEMS controller 100 outputs a setting signal (SetM) for returning the electric device 200 to the setting state (M) (S7-1). When the electric device 200 receives the signal, the electric device 200 returns a signal (SetM_Res) indicating that the signal has been received to the HEMS controller 100 (S7-2).

  As described above, in the control system according to the present embodiment, when there is an instruction from the portable terminal 400, the HEMS controller 100 acquires and stores the setting state of the electric device 200. Then, the timer is activated, and after a predetermined time has elapsed, a setting signal for setting the stored state to the electric device 200 is transmitted. As a result, for example, in order to maintain a comfortable environment for visitors, etc., when there is nobody temporarily in a space where the electrical equipment needs to be on at all times, the electrical equipment is temporarily stopped from outside the house to save energy. Can be made. Therefore, the setting of the electric device can be changed from the portable terminal 400, and the electric device can be returned to the original setting state after a certain period of time, so that convenience by remote control is improved. Further, for example, even when the electric device 200 that has been in the OFF state is turned on from a place where the user is away from home, the electric device 200 returns to the OFF state after a predetermined time has elapsed, and thus can be used more safely.

[Second Embodiment]
Similar to the control system according to the first embodiment, the HEMS controller 100 acquires the setting state of the electric device 200 when an instruction is given from the mobile terminal 400, as in the control system according to the first embodiment. And save. Then, the timer is activated, and after a predetermined time has elapsed, a setting signal for setting the stored state to the electric device 200 is transmitted.

  FIG. 7 is a diagram illustrating an example of an outline of operation in the control system when an instruction is transmitted from the mobile terminal 400 according to the second embodiment. FIG. 7 shows an example of a signal flow between elements in the control system.

  The operations from steps S1 to S6 in FIG. 7 are the same as those in the first embodiment. In FIG. 7, a timer extension control instruction (S <b> 8) is transmitted from the portable terminal 400 after a predetermined time (before the timer expires) after step S <b> 6, and the transmitted control instruction is transmitted to the HEMS via the server 300. It is transmitted to the controller 100 (S9).

  The HEMS controller 100 extends the timer based on the instruction from the portable terminal 400 (S10). In FIG. 7, the timer is extended once, but can be extended a plurality of times.

  Although illustration is omitted, the HEMS controller 100 returns to the set state (M) in which the electrical device 200 has been stored after the elapse of a certain time as in the first embodiment (S7). The HEMS controller 100 outputs a setting signal (SetM) for returning the electric device 200 to the setting state (M) (S7-1). When the electric device 200 receives the signal, the electric device 200 returns a signal (SetM_Res) indicating that the signal has been received to the HEMS controller 100 (S7-2).

  As described above, in the control system according to the second embodiment, the setting of the electric device can be changed from the portable terminal 400, and the electric device can be returned to the original setting state after a certain period of time, and the setting is maintained. Since the time can be adjusted, convenience by remote control is also improved. For example, since the electric device 200 that has been in the OFF state can be turned on from outside and the time for maintaining the ON state can be adjusted, the ON state can be maintained as necessary. Moreover, if it does not extend, it can return to the OFF state.

[Third Embodiment]
In the third embodiment, the flow of the HEMS controller 100 process in the above embodiment will be described in more detail with reference to FIG.

  Next, processing executed by the HEMS controller 100 in the control shown in FIGS. 6 and 7 will be described. In the process, the HEMS controller 100 can count a timer for each electric device 200. The timer is a control signal for the HEMS controller 100 to change the setting of the electric device 200 based on an instruction from the portable terminal 400 and then the HEMS controller 100 to return the setting state of the electric device 200 to the original state. Specify the time until transmission.

  In the present specification, the terms “start (or start)” and “extension” are used for the operation related to the timer. “Start” means that the timer expiration time is set to an initial value (for example, 2 hours, but is not limited to 2 hours), and the timing operation by the timer is started. The timer is running by starting the timer. “Extending” means extending the timer expiration time (for example, extending the expiration time from the initial value or resetting the count to 0).

  With reference to FIG. 8, the HEMS controller 100 receives the setting command of the electric equipment 200 by step S80. The setting command for the electric device 200 is a control signal transmitted to the HEMS controller 100 and includes a setting instruction for the electronic device 200.

  In step 81, the HEMS controller 100 determines whether the received setting command is a remote control. For example, if the command is via a public line such as the Internet, it can be said to be remote control. If it is determined that the command has been received via the public line, the control proceeds to step S83 (YES in step S82).

  On the other hand, when the HEMS controller 100 determines that the received setting command is not based on remote control (NO in step S81), the HEMS controller 100 transmits a command (SetC) based on the received setting command to the electrical device (step 82). The process of FIG. 8 is terminated.

  In step S <b> 83, the HEMS controller 100 acquires the setting state (M) of the electric device 200 from the electric device 200. The HEMS controller 100 transmits a setting state acquisition signal (Get) to the electric device 200 before transmitting the setting command (Set command) received in step S80. The setting state acquisition signal (Get) is a signal for acquiring the operation property of the electric device 200 as transmitted in step S3-1 of FIG. 6 and FIG. In step S83, the HEMS controller 100 transmits a state acquisition signal (Get) to the electrical device 200 that is the target of the Set command received in step S80. In step S83, the HEMS controller 100 receives a setting state response (Get_Res) to the setting state acquisition signal (Get) from the electric device 200. The setting state response (Get_Res) is a signal for acquiring the operation property of the electric device 200 as received in step S3-2 in FIG. 6 and FIG. Then, control proceeds to step S84.

  In step S84, the HEMS controller 100 stores the acquired setting state (M) of the electric device 200. Then, control proceeds to step S85.

  In step S85, a command (SetC) based on the received setting command is transmitted to the electrical device. Then, control proceeds to step S86.

  In step S86, the HEMS controller 100 starts a timer. The automatic stop timer started in step S86 is a timer for the electric device 200 that is the target of the Set command received in step S80. Then, the control proceeds to step S87. The timer operates for a certain period of time as shown in step S6 of FIGS.

  In step S87, the HEMS controller 100 determines whether or not a timer extension command has been received. If it is determined that the timer extension command has been received, the HEMS controller 100 proceeds to step S86 again (YES in step S87), and if it is determined that it has not been received, the control proceeds to step S88 (NO in step S87). The timer extension command is a control signal as received in step S9 of FIG.

  In step S88, the HEMS controller 100 stops the operation of the timer as the timer expires. Then, control proceeds to step S89.

  In step S90, the HEMS controller 100 transmits a setting signal (SetM) for returning the electric device 200 to the setting state (M) to the electric device 200, and ends the process of FIG.

  Thus, when the HEMS controller 100 receives a setting command for the electric device 200 by remote control, the HEMS controller 100 acquires and stores the setting state of the electric device 200. Then, the setting signal based on the received setting command is transmitted to the electric device 200 and the timer is operated, and the setting signal for setting the stored setting state is transmitted to the electric device 200 after a predetermined time has elapsed. To do.

  Note that the length of time measured by the timer can be changed for each electric device 200. Thereby, in the control system of the above-mentioned embodiment, the length of time until the command for returning to the original setting state is transmitted for every electric equipment 200 can be adjusted.

  As described above, in the control system according to the third embodiment, the setting of the electric device can be changed from the portable terminal 400 and the electric device can be returned to the original setting state after a certain period of time. Improves. Further, by extending the timer, it is possible to adjust the time for maintaining the changed setting state of the electric device, and the convenience is further improved.

[Fourth Embodiment]
The control system according to the fourth embodiment is used to remotely control an electric device 200 such as a home or office air conditioner using a portable terminal 400. The user of the mobile terminal 400 activates a remote operation application on the mobile terminal 400 and causes the touch panel 401 to display an operation image. When the user performs a touch operation on the touch panel 401 displaying the image, the portable terminal 400 outputs a control instruction to the electric device 200.

  In the control system, a control instruction transmitted from the portable terminal 400 is transmitted to the HEMS controller 100 via the server 300. Here, an outline of the operation of each element in the control system will be schematically described.

  FIG. 9 is a diagram illustrating an example of an outline of operation in the control system when an instruction from the mobile terminal 400 is transmitted. FIG. 9 shows an example of a signal flow between elements in the control system.

  Referring to FIG. 9, a control instruction (# 1) transmitted from portable terminal 400 is transmitted to HEMS controller 100 via server 300 (# 2). The HEMS controller 100 performs setting (C) on the electric device 200 based on an instruction from the portable terminal 400 (# 3). The HEMS controller 100 outputs a setting signal (SetC) for setting (C) (# 3-1). At this time, the HEMS controller 100 transmits a control signal that sets the value of “remote control property” to “via public line” along with the setting signal, and the setting signal (SetC) includes the remote control property. The CPU (electric device processor) of the electric device 200 stores the setting state (M) of the electric device 200 when the setting signal (SetC) is received (# 4). In addition, when receiving the setting signal (SetC), the electric device 200 returns a signal (SetC_Res) indicating that the signal has been received to the HEMS controller 100 (# 3-2).

  The set state of the electric device 200 includes ON / OFF of the electric device 200, a set operation amount (temperature, humidity, illuminance, etc.), and the like.

  The electric device 200 changes the setting of the electric device 200 to the setting (C) based on the instruction from the portable terminal 400, and operates the timer for a certain time (# 5).

  After a predetermined time has elapsed, the electric device 200 returns to the setting state (M) in which the setting state is stored (# 6).

  As described above, in the control system according to the fourth embodiment, if the setting command received by the electric device 200 is based on remote control, the electric device 200 stores the setting state. And the said electric equipment changes a state into the setting state of the received setting command, and returns to the setting state preserve | saved after progress for a fixed time. The remote control setting command received by the electric device 200 includes a “remote control property” value as a property value. The HEMS controller 100 that transmits a setting command to the electric device 200 manages the value of “remote control property” indicating whether the setting command is based on remote control, and the setting command received by the HEMS controller 100 is based on remote control. Distinguish whether or not there is. If the received setting command is control via the Internet from the portable terminal 400 or if the received setting command message includes a property (for example, 0x93) or a flag indicating that it is remote control, Judge that it is remote control. If the setting command is based on remote control, the HEMS controller 100 includes the property (for example, 0x93) indicating that the setting command is remote control and transmits the setting command to the electric device 200.

  As described above, in the control system according to the present embodiment, when there is an instruction from the mobile terminal 400, the electric device 200 acquires and stores the setting state. Then, the timer is activated, and after a predetermined time has elapsed, the stored setting state is restored. Therefore, the setting of the electric device can be changed from the portable terminal 400, and the electric device can be returned to the original setting state after a certain period of time, so that convenience by remote control is improved. Further, for example, even when the electric device 200 that has been in the OFF state is turned on from a place where the user is away from home, the electric device 200 returns to the OFF state after a predetermined time has elapsed, and thus can be used more safely.

[Fifth Embodiment]
As in the control system according to the fourth embodiment, the HEMS controller 100 transmits a setting signal to the electric device 200 when an instruction from the portable terminal 400 is received, as in the control system according to the fourth embodiment. To do. The electric device 200 that has received the setting signal stores the setting state. Then, the electric device 200 changes the setting based on the received setting signal, operates the timer, and returns to the stored setting state after a predetermined time has elapsed.

  FIG. 10 is a diagram illustrating an example of an outline of operation in the control system when an instruction is transmitted from the mobile terminal 400 according to the second embodiment. FIG. 10 shows an example of signal flow between elements in the control system.

  The operations from Step # 1 to Step # 5 in FIG. 10 are the same as those in the first embodiment described above. In FIG. 10, a timer extension control instruction (# 6) is transmitted from the portable terminal 400 after the step # 5 and before a lapse of a fixed time (before the timer expires), and the transmitted control instruction is transmitted via the server 300. Are transmitted to the HEMS controller 100 (# 7). The HEMS controller 100 transmits a timer extension instruction control signal to the electric device 200 (# 8). The electrical device 200 that has received the timer extension instruction control signal extends the timer (# 9). In FIG. 7, the timer is extended once, but can be extended a plurality of times.

  Although illustration is omitted, similar to the fourth embodiment described above, after a predetermined time has elapsed, the electric device 200 returns the setting state to the stored setting state (M) (# 6).

  As described above, in the control system according to the fifth embodiment, the setting of the electric device can be changed from the portable terminal 400, and the electric device can be returned to the original setting state after a certain period of time, and the setting is maintained. Since the time to perform can be adjusted, convenience by remote control is also improved. For example, since the electric device 200 that has been in the OFF state can be turned on from outside and the time for maintaining the ON state can be adjusted, the ON state can be maintained as necessary. Moreover, if it does not extend, it can return to the OFF state.

[Sixth Embodiment]
In the sixth embodiment, the flow of processing of the electric device 200 in the fourth and fifth embodiments will be described in more detail with reference to FIG.

  Processing executed by the HEMS controller 100 in the control shown in FIGS. 9 and 10 will be described. In the process, the electric device 200 counts a timer. The timer defines the time from when the electric device 200 performs control to change the setting of the electric device 200 based on an instruction from the portable terminal 400 to when the setting state is restored.

  Referring to FIG. 11, in step # 90, electric device 200 receives a setting command. The setting command is a control signal transmitted to the electric device 200 and includes a setting instruction for the electronic device 200.

  In step # 91, the electric device 200 determines whether the received setting command is by remote control. For example, if the command includes a remote control property indicating remote control, it can be said to be remote control. If it is “via public line”, it is remote control, and if it is determined that a command via the public line has been received, control proceeds to step # 93 (YES in step # 91).

  On the other hand, when determining that the received setting command is not based on remote control (NO in step # 91), the electric device 200 performs setting (SetC) based on the received setting command (step # 92), and FIG. End the process.

  In step # 93, the electric device 200 stores the setting state (M). Control then proceeds to step # 94.

  In step # 94, the electric device 200 changes the setting based on the setting command (SetC) received in step # 90. Then, control proceeds to step # 95.

  In step # 95, electric device 200 starts a timer. Then, control proceeds to step # 96. The timer runs for a certain period of time as shown in step # 5 of FIGS.

  In step # 96, electric device 200 determines whether or not a timer extension command has been received. When it is determined that the timer extension command has been received, the electric device 200 proceeds to step # 95 again (YES in step # 96), and when it is determined that it has not been received, the control proceeds to step # 97 (step # 96). NO). The timer extension command is a control signal as received at step # 8 of FIG.

  In step # 97, the electric device 200 stops the operation of the timer as the timer expires. Then, control proceeds to step # 98.

  In step # 98, the electric device 200 is returned to the set state (M), and the process of FIG. 11 is terminated.

  In this way, the electric device 200 stores the setting state of the electric device 200 when receiving a setting command for the electric device 200 by remote control. Then, the setting is changed to the setting based on the received setting command and the timer is operated, and after a predetermined time has elapsed, the stored setting state is restored.

  As described above, in the control system according to the sixth embodiment, the setting of the electric device can be changed from the portable terminal 400 and the electric device can be returned to the original setting state after a certain period of time. Improves. Further, by extending the timer, it is possible to adjust the time for maintaining the changed setting state of the electric device, and the convenience is further improved.

[Seventh Embodiment]
The control system according to the seventh embodiment is the same as the control system according to the first embodiment, and the server 300 has the function of the HEMS controller 100 in the first embodiment. In the control system according to the seventh embodiment, when there is an instruction from the mobile terminal 400, the server 300 acquires and stores the setting state of the electric device 200. Then, the timer is activated, and after a predetermined time has elapsed, a setting signal for setting the stored state to the electric device 200 is transmitted.

  FIG. 12 is a diagram illustrating an example of an outline of operation in the control system when an instruction from the mobile terminal 400 is transmitted. FIG. 12 shows an example of a signal flow between elements in the control system.

  Referring to FIG. 12, when a control instruction is transmitted from portable terminal 400 (T1), server 300 acquires a setting state of electric device 200 in accordance with the instruction from portable terminal 400 (T2). As an example of the operation of acquiring the setting state, the server 300 sends a setting state acquisition signal (Get) to the electric device 200 to inquire about the setting state (T2-1), and sends a response (Get_Res) from the electric device 200. Receive (step T2-2). As another example, the server 300 receives a state change announcement notification (INF) from the electrical device 200. The state change announcement notification (INF) is a notification transmitted when the electric device 200 has changed in the state of the electric device 200.

  The set state of the electric device 200 includes ON / OFF of the electric device 200, a set operation amount (temperature, humidity, illuminance, etc.), and the like.

  In the control system according to the seventh embodiment, when the server 300 receives the setting state response from the electric device 200, the processor (CPU) of the server 300 stores the setting state (M) in the memory (T3).

  Server 300 performs setting (C) based on an instruction from portable terminal 400 for electric device 200 (T4). The server 300 outputs a setting signal (SetC) for setting (C) (T4-1). When the electric device 200 receives the signal, the electric device 200 returns a signal (SetC_Res) indicating that the signal has been received to the HEMS controller 100 (T4-2).

  The server 300 operates the timer for a certain time after performing the setting (C) based on the instruction from the portable terminal 400 for the electric device 200 (T5).

  After a predetermined time has elapsed, the server 300 returns the electric device 200 to the stored setting state (M) (T6). The server 300 outputs a setting signal (SetM) for returning the electric device 200 to the setting state (M) (T6-1). When the electric device 200 receives the signal, the electric device 200 returns a signal (SetM_Res) indicating that the signal has been received to the server 300 (T6-2).

  As described above, in the control system according to the present embodiment, the setting of the electric device can be changed from the portable terminal 400 and the electric device can be returned to the original setting state after a certain period of time. improves. Further, for example, even when the electric device 200 that has been in the OFF state is turned on from a place where the user is away from home, the electric device 200 returns to the OFF state after a predetermined time has elapsed, and thus can be used more safely.

[Eighth Embodiment]
The control system according to the eighth embodiment is the same as the control system according to the second embodiment, and the server 300 includes the function of the HEMS controller 100 in the second embodiment. When receiving an instruction from the mobile terminal 400, the server 300 acquires and stores the setting state of the electric device 200. Then, the timer is activated, and after a predetermined time has elapsed, a setting signal for setting the stored state to the electric device 200 is transmitted.

  FIG. 13 is a diagram illustrating an example of an outline of operation in the control system when an instruction is transmitted from the mobile terminal 400 according to the eighth embodiment. FIG. 13 shows an example of a signal flow between elements in the control system.

  The operations from steps T1 to T5 in FIG. 13 are the same as those in the first embodiment. In FIG. 13, a timer extension control instruction (T <b> 7) is transmitted from the portable terminal 400 after the predetermined time (before the timer expires) after step T <b> 5.

  The server 300 extends the timer based on the instruction from the portable terminal 400 (T8). In FIG. 13, the timer is extended once, but can be extended a plurality of times.

  Although illustration is omitted, the server 300 returns to the set state (M) in which the electrical device 200 has been stored after a predetermined time has passed (T6), as in the first embodiment described above. The server 300 outputs a setting signal (SetM) for returning the electric device 200 to the setting state (M) (T6-1). When the electric device 200 receives the signal, the electric device 200 returns a signal (SetM_Res) indicating that the signal has been received to the server 300 (T6-2).

  As described above, in the control system according to the eighth embodiment, the setting of the electric device can be changed from the portable terminal 400, and the electric device can be returned to the original setting state after a certain time has elapsed, and the setting is maintained. Since the time can be adjusted, convenience by remote control is also improved. For example, since the electric device 200 that has been in the OFF state can be turned on from outside and the time for maintaining the ON state can be adjusted, the ON state can be maintained as necessary. Moreover, if it does not extend, it can return to the OFF state.

  In the above embodiment, the HEMS controller 100 communicates with the mobile terminal 400 via the server 300. However, the HEMS controller 100 and the mobile terminal 400 are configured to communicate directly via the public line network. May be.

  It should be thought that embodiment disclosed this time and its modification are illustrations in all the points, and are not restrictive. The scope of the present disclosure is defined by the terms of the claims, rather than the description above, and is intended to include any modifications within the scope and meaning equivalent to the terms of the claims.

100 HEMS controller, 200 electrical equipment, 300 server, 400 portable terminal.

Claims (7)

A controller for transmitting a control signal to an electrical device,
A memory for storing a setting state of the electric device;
With a processor,
The processor is
When receiving an instruction for the electrical device by remote control,
Obtaining the setting state of the electrical device and storing the setting state in a memory;
While sending a control signal based on the received instruction to the electrical device, to start a timer,
A controller that transmits, to the electric device, a control signal for changing the electric device to a stored state when the timer expires. An electrical device that receives a control signal by remote control,
A memory for storing a setting state of the electric device;
An electrical equipment processor,
The electrical equipment processor is
When receiving an instruction for the electrical device by remote control,
Save the setting state of the electrical device in a memory,
An electric device that changes the setting of the electric device based on the received instruction, starts a timer, and changes the electric device to a stored state when the timer expires. Server,
A controller for transmitting a control signal to an electrical device;
A control system comprising electrical equipment,
The controller is
When a setting instruction for the electrical device is received from the server,
Get the setting status of the electrical equipment,
Save the acquired setting state,
A control signal for changing the setting of the electrical device based on the received setting instruction for the electrical device;
Start the timer,
A control system configured to transmit a control signal for changing the electrical device to a stored state when the timer expires, to the electrical device. Electrical equipment,
A control system comprising a controller for transmitting a control signal to the electrical device,
When the controller receives a setting instruction for the electric device by remote control, the controller transmits a control signal including a remote control property to the electric device,
The electrical equipment is
If the received control signal contains a remote control property, save the setting state of the electrical device,
Change the setting of the electrical device based on the received control signal,
Start the timer,
A control system configured to change the electrical device to a stored state upon expiration of a timer. A control method of a controller for transmitting a control signal to an electric device,
Receiving instructions for electrical equipment;
Determining whether the instruction is by remote control;
If the instruction is by remote control,
Obtaining a setting state of the electrical device;
Storing the acquired setting state in a memory;
Transmitting a control signal to the electrical device based on the received instruction;
Starting a timer;
And a step of transmitting a control signal for setting the electric device to the stored setting state when the timer expires. A method of controlling an electrical device that receives a control signal by remote control,
The electrical device is
Receiving instructions for the electrical device by remote control;
Storing a setting state of the electrical device;
Changing the setting of the electrical device based on the received instruction;
Starting a timer;
And a step of changing the electrical device to the stored setting state when the timer expires. Receiving an instruction to extend the timer before the timer expires;
The control method according to claim 5, further comprising the step of extending the timer.

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