JP2012134957A - Controller and information processing method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a controller and an information processing method which can make a user easily recognize the usage state, operation state, and the like of a device.SOLUTION: A controller 100 comprises: a communication interface 105 for receiving respective power consumption of a plurality of devices; a memory 101 for storing the respective power consumption of the plurality of devices; and a processor 110 for determining the state of the devices based on the respective power consumption of the plurality of devices, and outputting information indicating the state of the devices by associating it with each of the plurality of devices.

Description

  The present invention relates to a technology of a controller connected to an electric device arranged in a house or an office.

  There has been proposed a controller that is arranged in a house or the like and controls electric equipment in the house. For example, a technology has been proposed in which a controller controls an air conditioner, a TV, a curtain opening / closing device, a refrigerator, a washing machine, a microwave oven, a solar cell, and the like, and displays the status of these devices. Yes.

  Japanese Patent Application Laid-Open No. 09-145743 (Patent Document 1) discloses a current usage amount detection adapter and its application system. According to Japanese Patent Application Laid-Open No. 09-145743 (Patent Document 1), a current flow rate detection circuit unit detects the amount of current flowing into a device, and when the current amount is abnormally large, a command from a control processing unit causes a current cutoff circuit unit to The current can be cut off. Further, the communication processing unit can transmit / receive the detected current amount and current amount control information to / from the controller connected on the bus, and can grasp the use status of multiple devices and determine abnormality.

JP 09-145743 A

  Currently, from the viewpoint of environmental protection, there is a demand for more effective energy saving awareness among users who use home appliances. For example, it is beneficial if the user can be made aware of the amount of electricity used at a preferred timing according to the usage state of the home appliance.

  The present invention has been made to solve such a problem, and an object of the present invention is to provide a controller and an information processing method that allow a user to easily recognize a use state or an operation state of a device. .

  A controller according to an aspect of the present invention includes a communication interface for receiving power consumption of a plurality of devices, a memory for storing power consumption of each of the plurality of devices, and a device based on the power consumption of each of the plurality of devices. And a processor that outputs information indicating the state of the device in association with each of the plurality of devices.

  Preferably, when the power consumption of any of the plurality of devices is equal to or greater than the first threshold, the processor is associated with any of the plurality of devices and indicates that any of the plurality is in use. 1 image is output. Then, when the power consumption of any of the plurality of devices is less than the first threshold, the second image indicating that any of the plurality of devices is not used in association with any of the plurality of devices. Output.

Preferably, the first threshold is set corresponding to each of the plurality of devices.
Preferably, the processor outputs the first image in association with any of the plurality of devices when the power consumption of any of the plurality of devices is equal to or greater than the first threshold value. When the power consumption of any of the plurality of devices is equal to or greater than a second threshold value that is less than the first threshold value and smaller than the first threshold value, the second image is associated with one of the plurality of devices. Output. Then, when the power consumption of any of the plurality of devices is less than the second threshold, the third image is output in association with any of the plurality of devices.

  Preferably, the first threshold value is set corresponding to each of the plurality of devices, and the second threshold value is set corresponding to each of the plurality of devices.

  Preferably, the processor acquires the integrated power consumption of each of the plurality of devices, and corresponds to any of the plurality of devices when the integrated power consumption of any of the plurality of devices is equal to or greater than a third threshold. In addition, a fourth image indicating that any one of the plurality of devices is overused is output.

Preferably, the third threshold value is set corresponding to each of the plurality of devices.
Preferably, the memory stores a correspondence relationship between each of the plurality of devices and a room in which the device is disposed, and the processor indicates each state of the plurality of devices by referring to the correspondence relationship of the memory. Information is output in association with the room in which the device is placed.

  Preferably, the memory stores a floor plan representing a plurality of rooms in which a plurality of devices are arranged, and positions of the plurality of devices in the floor plan. The processor refers to the memory and outputs information indicating the states of the plurality of devices in association with the positions of the plurality of devices in the floor plan.

  Preferably, the controller further comprises a display. The processor displays information indicating the states of the plurality of devices on the display.

  Preferably, the communication interface is communicable with an external display. The processor causes the external display to display information indicating the states of the plurality of devices via the communication interface.

  Preferably, the processor receives an instruction for selecting one device from a plurality of devices, and outputs information indicating transition of power consumption of one device by referring to the memory.

  Preferably, the memory stores a message in association with the device and the state, and the processor accepts an instruction for selecting one device from the plurality of devices, and the state corresponds to one device and one device. Output a message corresponding to.

  Preferably, the processor receives power consumption from each of the plurality of devices via the communication interface.

  Preferably, the processor receives information indicating that any of the plurality of devices is in failure from any of the plurality of devices via the communication interface, and associates the information with any of the plurality of devices. A fifth image indicating that any of the plurality of devices is malfunctioning is output.

  Preferably, the processor receives power consumption from a plurality of communication devices for measuring power consumption of each of the plurality of devices via the communication interface.

  A controller according to still another aspect of the present invention is based on a communication interface for receiving power consumption of a plurality of devices, a memory for storing power consumption of each of the plurality of devices, and power consumption of each of the plurality of devices. A processor that determines the state of the device and outputs information indicating the state of the device in association with each of the plurality of devices.

  When the power consumption of any of the plurality of devices is greater than or equal to the first threshold, the processor associates with one of the plurality of devices and indicates that one of the plurality is in use And when the power consumption of any of the plurality of devices is less than the first threshold, the second indicating that any of the plurality of devices is not used in association with any of the plurality of devices. Output the image.

  Further, the processor acquires the power consumption amount of each of the plurality of devices, and associates with any of the plurality of devices when the acquired power consumption amount of any of the plurality of devices is equal to or greater than a third threshold. Thus, an image indicating that any one of the plurality of devices is overused is output.

  According to still another aspect of the present invention, an information processing method in a controller including a communication interface, a memory, and a processor includes a step in which the processor receives power consumption of a plurality of devices via the communication interface, and a plurality of memories Storing the power consumption of each of the devices, a step of determining a state of the device based on the power consumption of each of the plurality of devices, and a processor corresponding to each of the plurality of devices Outputting information indicating the state.

  As described above, according to the present invention, there is provided a controller and an information processing method that allow a user to easily recognize a use state and an operation state of a device.

It is an image figure which shows the whole structure of the network system 1 which concerns on this Embodiment. It is an image figure which shows the display 102 of the controller 100 which concerns on this Embodiment, or the display 202 of the television 200B. It is a block diagram showing the hardware constitutions of the home controller 100 which concerns on this Embodiment. It is an image figure which shows 101 A of power consumption tables which concern on this Embodiment. It is an image figure which shows the comment table 101B which concerns on this Embodiment. It is an image figure which shows the display screen 101C which concerns on this Embodiment. It is a block diagram showing the hardware constitutions of the television 200B which concerns on this Embodiment. It is a flowchart which shows the process sequence of the information processing in the home controller 100 which concerns on this Embodiment. It is a flowchart which shows the process sequence of the information processing in the television 200B which concerns on this Embodiment. It is an image figure which shows the whole structure of the network system 1B which concerns on this Embodiment.

  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.

[Embodiment 1]
<Overall configuration of network system>
First, the overall configuration of the network system according to the present embodiment will be described. FIG. 1 is an image diagram showing an overall configuration of a network system 1 according to the present embodiment.

  Referring to FIG. 1, network system 1 according to the present embodiment is installed in, for example, a house or an office. The network system 1 includes an air conditioner 200A installed in a living room, a television 200B installed in the living room, a curtain opening / closing device 200C installed in the living room, a refrigerator 200D installed in the kitchen, and a dining room. Household appliances (electric equipment) such as the light 200E.

  The network system 1 includes a solar power generation device 200X, a battery 200Y, and a power conditioner 200Z for controlling them. The battery 200Y may be installed in a house or the like, or may be an automobile battery that is also used as a house battery.

  The network system 1 includes a home controller 100 for controlling home appliances 200A to 200E, a solar power generation device 200X, a battery 200Y, a power conditioner 200Z for controlling them, and the like. The home controller 100 can perform data communication with the home appliances 200A to 200E, the solar power generation device 200X, the battery 200Y, and the power conditioner 200Z for controlling them via a wired or wireless network 401.

  The home controller 100 uses, for example, a wireless LAN, ZigBee (registered trademark), Bluetooth (registered trademark), wired LAN (Local Area Network), or PLC (Power Line Communications) as the network 401. The home controller 100 may be portable, may be detachable from a base placed on a table, or may be fixed to a wall of a room.

  In network system 1 according to the present embodiment, power conditioner 200Z supplies power to battery 200Y, the grid, and home appliances 200A to 200E via power line 402. And the power conditioner 200Z acquires electric power from the solar power generation device 200X, the battery 200Y, and the system via the power line 402.

<Overview of network system operation>
Next, an outline of the operation of the network system 1 according to the present embodiment will be described. FIG. 2 is an image diagram showing display 102 of controller 100 or display 202 of television 200B according to the present embodiment.

  Referring to FIGS. 1 and 2, home controller 100 according to the present embodiment includes power consumption of home appliances 200A to 200E from each of a plurality of home appliances 200A to 200E installed in a house via network 401. Receives operating status and input commands.

  The home controller 100 determines whether or not the power consumption of the home appliances 200A to 200E satisfies a predetermined condition by sequentially accumulating the received power consumption and operation state of the home appliances 200A to 200E and the input command. Home controller 100 according to the present embodiment is based on the power consumption and the integrated value of power consumption, whether or not household appliances 200A to 200E are in use or unused, or whether or not household appliances 200A to 200E are overused. To determine. Home controller 100 determines whether or not home appliances 200A to 200E are out of order based on information from home appliances 200A to 200E. Further, the home controller 100 calculates and displays the power consumption of the entire house from the received power consumption of the home appliances 200A to 200E, or acquires and displays the power consumption of the entire house from the power conditioner 200Z (see FIG. 2).

  Home controller 100 displays the status of home appliances 200A to 200E on display 102 in association with home appliances 200A to 200E (for example, at a location corresponding to the position where home appliances 200A to 200E are arranged on the floor plan). More specifically, the home controller 100 displays a state based on the following priorities when each of the home appliances 200A to 200E corresponds to two or more states.

  That is, the home controller 100 sets the home appliances 200 </ b> A to 200 </ b> E in the order of an image indicating failure, an image indicating excessive use, an image indicating use, and an image indicating nonuse. Display status. For example, when the air conditioner 200A is overused and being used, the home controller 100 displays an image indicating that the air conditioner 200A is overused at a location corresponding to the installation position of the air conditioner 200A.

  Home controller 100 also causes display 202 of television 200B to display information indicating the states of home appliances 200A to 200E at locations corresponding to positions where home appliances 200A to 200E are arranged on the floor plan.

  The home controller 100 may display the current power consumption of the home appliances 200A to 200E on the displays 102 and 202 in association with the home appliances 200A to 200E (in the vicinity of the home appliances 200A to 200E).

  Thus, the network system 1 according to the present embodiment can inform the user of the usage state and the operating state of each of the home appliances 200A to 200E. For example, since the home controller 100 can notify the resident that any of the home appliances 200A to 200E is in use, the resident can easily notice that the home appliances 200A to 200E are forgotten to be turned off. In addition, the home controller 100 can inform the resident that the household appliances 200A to 200E are being used excessively or that the household appliances 200A to 200E are out of order.

  Hereinafter, a specific configuration of the network system 1 for realizing such a function will be described in detail.

<Hardware configuration of home controller 100>
One aspect of the hardware configuration of home controller 100 according to the present embodiment will be described. FIG. 3 is a block diagram showing a hardware configuration of home controller 100 according to the present embodiment.

  The home controller 100 includes a memory 101, a display 102, a tablet 103, a button 104, a communication interface 105, a speaker 107, a clock 108, and a CPU (Central Processing Unit) 110.

  The memory 101 is realized by various types of RAM (Random Access Memory), ROM (Read-Only Memory), a hard disk, and the like. For example, the memory 101 is a USB (Universal Serial Bus) memory, a CD-ROM (Compact Disc-Read Only Memory), a DVD-ROM (Digital Versatile Disk-Read Only Memory), which is used via a reading interface. USB (Universal Serial Bus) memory, memory card, FD (Flexible Disk), hard disk, magnetic tape, cassette tape, MO (Magnetic Optical Disc), MD (Mini Disc), IC (Integrated Circuit) card (excluding memory cards) It is also realized by a medium for storing a program in a nonvolatile manner such as an optical card, a mask ROM, an EPROM, and an EEPROM (Electronically Erasable Programmable Read-Only Memory).

  The memory 101 stores a control program executed by the CPU 110, a power consumption table 101A, a comment table 101B, a display screen 101C, and a floor plan 101D of a house or office where the network system 1 is installed.

  FIG. 4 is an image diagram showing a power consumption table 101A according to the present embodiment. Referring to FIG. 4, power consumption table 101A includes, for each home appliance 200A to 200E, that is, for each home appliance ID, the name of the home appliance, the ID and name of the room in which the home appliance is installed, the power consumption, and the integration. The power consumption amount, the average integrated power consumption amount, the usage state of the home appliance, the time after the start of the usage state, and the coordinates indicating the position of the home appliance in the floor plan are stored.

  Furthermore, the power consumption table 101A stores the instantaneous power consumption received from each of the home appliances 200A to 200E and the date and time when the instantaneous power consumption is received (measured) in association with each other and stored as time series data. The CPU 110 may calculate the integrated power consumption and / or the average integrated power consumption as needed based on the time series data.

  FIG. 5 is an image diagram showing the comment table 101B according to the present embodiment. Referring to FIG. 5, comment table 101B stores comments to be displayed to the user in association with home appliances 200A to 200E and states. The comment is preferably one that increases the user's awareness of energy saving. In the present embodiment, the comment table 101B stores, for each home appliance 200A to 200E, a comment to be displayed when overuse and a comment to be displayed at the time of failure.

  Furthermore, the comment table 101B may store, for each of the home appliances 200A to 200E, a comment to be displayed during use and a comment to be displayed when not in use. For example, when home appliances 200A to 200E are in use, home controller 100 has a comment “Used for XX hours” or “Current power consumption is XXW” on a detailed screen described later. Comments may be displayed.

  FIG. 6 is an image diagram showing a display screen 101C according to the present embodiment. Referring to FIG. 6, memory 101 stores a plurality of display screens 101C having a hierarchical structure. As will be described later, the CPU 110 receives a selection command (and determination command) for a predetermined area of the display screen, and based on the hierarchical structure, the home appliances 200A to 200E, the solar power generation device 200X, the battery 200Y, and the power conditioner. A screen for displaying simple information about 200Z and a screen for displaying detailed information are output.

  Returning to FIG. 3, the display 102 displays the states of the home appliances 200 </ b> A to 200 </ b> E, the solar power generation device 200 </ b> X, the battery 200 </ b> Y, and the power conditioner 200 </ b> Z by being controlled by the CPU 110. The tablet 103 detects a touch operation with a user's finger and inputs touch coordinates or the like to the CPU 110. The CPU 110 receives a command from the user via the tablet 103.

  In the present embodiment, a tablet 103 is laid on the surface of the display 102. That is, in the present embodiment, display 102 and tablet 103 constitute touch panel 106. However, the home controller 100 may not have the tablet 103.

  The button 104 is disposed on the surface of the home controller 100. A plurality of buttons such as a determination key, a direction key, and a numeric keypad may be arranged on the home controller 100. The button 104 receives a command from the user. The button 104 inputs a command from the user to the CPU 110.

  The communication interface 105 transmits / receives data to / from the home appliances 200 </ b> A to 200 </ b> E, the solar power generation device 200 </ b> X, the battery 200 </ b> Y, and the power conditioner 200 </ b> Z through the network 401 by being controlled by the CPU 110. As described above, the communication interface 105 uses, for example, a wireless LAN, ZigBee (registered trademark), Bluetooth (registered trademark), a wired LAN, or a PLC, so that the home appliances 200A to 200E, the solar power generation device 200X, Data is transmitted / received to / from the battery 200Y and the power conditioner 200Z.

  The speaker 107 outputs sound based on a command from the CPU 110. For example, the CPU 110 causes the speaker 107 to output sound based on the sound data.

  The clock 108 inputs the current date and time to the CPU 110 based on a command from the CPU 110.

The CPU 110 executes various types of information processing by executing various programs stored in the memory 101. In other words, the processing in the home controller 100 is realized by each hardware and software executed by the CPU 110. Such software may be stored in the memory 101 in advance. The software may be stored in a storage medium and distributed as a program product. Alternatively, the software may be provided as a program product that can be downloaded by an information provider connected to the so-called Internet.

  Such software is read from the storage medium by using a reading device (not shown), or downloaded by using the communication interface 105 and temporarily stored in the memory 101. The CPU 110 stores the software in the form of an executable program in the memory 101 and then executes the program.

As storage media, CD-ROM (Compact Disc-Read Only Memory), DVD-ROM (Digital Versatile Disk-Read Only Memory), USB (Universal Serial Bus) memory, memory card, FD (Flexible Disk), hard disk , Magnetic tape, cassette tape, MO (Magnetic Optical Disc), MD (Mini Disc
), IC (Integrated Circuit) card (except memory card), optical card, mask R
Examples include a medium for storing a program in a nonvolatile manner such as OM, EPROM, and EEPROM (Electronically Erasable Programmable Read-Only Memory).

  The program here includes not only a program directly executable by the CPU but also a program in a source program format, a compressed program, an encrypted program, and the like.

  More specifically, the CPU 110 according to the present embodiment receives the power consumption and the operating state of the home appliances 200A to 200E from each of the plurality of home appliances 200A to 200E installed in the house via the communication interface 105. Receive commands. CPU110 displays the information regarding household appliances 200A-200E, the solar power generation device 200X, the battery 200Y, and the power conditioner 200Z on the display 102 based on a user's command. Alternatively, the CPU 110 transmits information to the television 200B via the communication interface 105.

  CPU 110 receives power consumption from home appliances 200 </ b> A to 200 </ b> E via communication interface 105. CPU110 accumulate | stores transition of the power consumption of household appliances 200A-200E in the memory 101. FIG. CPU 110 causes display 102 and television 200 </ b> B to simultaneously display the respective states (simple information) of home appliances 200 </ b> A to 200 </ b> E based on the power consumption of home appliances 200 </ b> A to 200 </ b> E. CPU110 displays the transition (detailed information) of the power consumption of selected household appliances 200A-200E on display 102 and television 200B based on the selection command of household appliances 200A-200E.

  More specifically, in the present embodiment, as shown in FIG. 6, CPU 110 accepts a display switching command from the user, and displays on display 102 or display 202 based on the hierarchical structure of the display screen of memory 101. Display multiple types of screens.

  For example, the CPU 110 displays a main screen as shown in FIG. CPU110 will display a solar power generation screen, as shown in FIG.6 (b), if the selection command of the energy monitoring screen is received from the user via the touch panel 106. FIG.

  When the solar power generation screen is displayed, the CPU 110 receives, from the power conditioner 200Z, information indicating the power generated by the solar power generation device 200X, the power purchased and sold to the system, and the power discharged to the battery 200Y. CPU110 displays the information regarding the electric power generated by the solar power generation device 200X, the electric power purchased and sold to the system, and the electric power discharged to the battery 200Y as the solar power generation screen.

  The battery 200Y may be an electric vehicle (EV) battery. The network system 1 may include an EV battery and a battery installed in a house.

  The CPU 110 causes the displays 102 and 202 to display an image (such as an icon or an arrow) indicating whether or not the EV battery is connected to the home power system. The CPU 110 causes the displays 102 and 202 to display images (icons or arrows or the like) indicating whether the EV battery and the house battery are not being charged or discharged.

  The CPU 110 displays information indicating the trading power from the commercial power system, the remaining amount of the battery 200Y, the stored or discharged power of the battery 200Y, the power generated by the solar power generation device 200X, and the power consumed by the load on the house. To display. Preferably, the CPU 110 displays an arrow indicating the flow of power from the commercial power system, EV battery, residential battery, solar power generation device, and the like to the load on the house and a number indicating the power on the displays 102 and 202. Display.

  More specifically, when an EV battery is connected to the CPU 110 and electric power is supplied from the EV battery to a load on the house, the CPU 110 displays an arrow extending from the EV battery to the house and the supply amount. Displayed on the displays 102 and 202. When an EV battery is connected to the CPU 110 and electric power is supplied to the EV battery, an arrow extending from the commercial power system and / or the solar power generation device 200X to the EV battery and the supplied power Are displayed on the displays 102 and 202.

  Similarly, the CPU 110 extends from the home battery (commercial power system, solar power generation device) to the home when power is supplied from the home battery (commercial power system, solar power generation device) to the load on the home. The arrows and the supplied power are displayed on the displays 102 and 202. When power is supplied to the battery of the house, the CPU 110 displays on the displays 102 and 202 an arrow extending from the commercial power system and / or the solar power generation device 200X to the battery of the house and the supplied power. Let Further, when power is supplied to the commercial power system, the CPU 110 displays the arrows and the supplied power that extend from the residential battery and / or the solar power generation device 200X to the commercial power system and the supplied power. To display.

  For example, 1200 W of power consumed by a house load corresponds to 600 W associated with an arrow extending from the house battery to the house load and an arrow extending from the photovoltaic power generation apparatus 200X to the house load. It is displayed that the power is covered by the attached 600W electric power. In a state where the EV battery is connected, it is displayed that the power of 3290 W consumed by the house load is covered only by the power of 3290 W associated with the arrow extending from the EV battery to the house load. Is done.

  CPU110 will display a household appliance monitoring screen, as shown in FIG.6 (c) and FIG. 2, if the selection command of the household appliance monitoring screen is received from the user via the touch panel 106. FIG. The CPU 110 reads the floor plan 101D from the memory 101. CPU110 acquires the position (coordinate) of household appliances 200A-200E in a floor plan with reference to the power consumption table 101A.

  CPU110 reads the use condition of household appliances 200A-200E from power consumption table 101A. CPU 110 causes touch panel 106 to display images 120a to 120d indicating the states of home appliances 200A to 200E at the positions of home appliances 200A to 200E on the floor plan, respectively. CPU 110 causes television 200B to display images 120a to 120d indicating the states of home appliances 200A to 200E via communication interface 105.

  More specifically, in this embodiment, when any of the home appliances 200A to 200E is out of order, the CPU 110 is in trouble from any of the home appliances 200A to 200E through the communication interface 105. The information indicating is received. CPU110 displays on the touch panel 106 the image 120d which shows that it is in failure as any state of the household appliances 200A-200E. The CPU 110 also displays the image 120d on the television 200B via the communication interface 105.

  In other words, in the present embodiment, CPU 110 includes, for each home appliance 200A to 200E, image 120a indicating that home appliances 200A to 200E are in use, image 120b indicating that home appliances 200A to 200E are not used, and home appliances. One of the image 120c indicating that 200A to 200E is overused and the image 120d indicating that the home appliances 200A to 200E are out of order is output.

  With reference to FIG.6 (d), CPU110 receives the command for selecting household appliances 200A-200E. Or CPU110 receives the command for selecting the place where household appliances 200A-200E are installed. For example, CPU 110 accepts a selection command for home appliances 200 </ b> A to 200 </ b> E via touch panel 106.

  Or CPU110 changes household appliances 200A-200E currently selected according to the direction key of button 104, and receives selection instructions of household appliances 200A-200E according to pressing of a decision key. Alternatively, CPU 110 accepts a selection command from television 200B.

  More specifically, in the present embodiment, CPU 110 causes image 120A indicating the state of selected home appliances 200A to 200E to be displayed in a state different from the other images 120a to 120d (a state larger than normal). .

  CPU 110 causes touch panel 106 to display detailed information (for example, transition of power consumption) corresponding to selected home appliances 200A to 200E. More specifically, the CPU 110 refers to the comment table 101B and causes the touch panel 106 to display comments corresponding to the selected home appliances 200A to 200E and the state. CPU 110 causes television 200 </ b> B to display detailed information and comments corresponding to selected home appliances 200 </ b> A to 200 </ b> E via communication interface 105.

  As described above, in the present embodiment, CPU 110 does not use image 120a (image 120A) and home appliances 200A to 200E indicating that home appliances 200A to 200E are in use for each of home appliances 200A to 200E. One of the image (120b) indicating that the home appliances 200A to 200E are overused, and the image (120d) indicating that the home appliances 200A to 200E are out of order are output. . However, CPU110 may output the image which shows the other use condition regarding household appliances 200A-200E.

  As a modification, the memory 101 stores a plurality of power consumption threshold values together with the integrated power consumption and the average integrated power consumption or instead of the integrated power consumption and the average integrated power consumption. For example, the memory 101 stores the standby power of each of the home appliances 200A to 200E and the power consumption during normal operation. CPU110 compares the power consumption received from household appliances 200A-200E, the standby power corresponding to household appliances 200A-200E, and the power consumption during normal operation.

  CPU110 is an image which shows that household appliance 200A-200E is consuming electric power larger than the power consumption at the time of normal driving for every household appliance 200A-200E, and household appliances 200A-200E are more than the power consumption at the time of normal driving. Either an image indicating that the power consumption is smaller and larger than the standby power, or an image indicating that the home appliances 200A to 200E consume less power than the standby power (not used) is output.

  Moreover, it is not restricted to the form which outputs the image which shows the use condition regarding household appliances 200A-200E on a floor plan. For example, CPU 110 may display home appliances 200 </ b> A to 200 </ b> E and texts or images indicating their states in association with each other as a list. That is, based on the power consumption of the home appliances 200A to 200E, the CPU 110 informs the user of the state of the home appliances 200A to 200E at a glance for each of the home appliances 200A to 200E via the touch panel 106 or the television 200B.

  CPU 110 may display current power consumption of home appliances 200A to 200E on displays 102 and 202 in association with home appliances 200A to 200E on the floor plan (in the vicinity of home appliances 200A to 200E). Alternatively, the CPU 110 may display the current power consumption of the home appliances 200A to 200E on the displays 102 and 202 in association with the home appliances 200A to 200E on the list.

<Hardware configuration of TV 200B>
One aspect of the hardware configuration of television 200B according to this embodiment will be described. FIG. 7 is a block diagram showing a hardware configuration of television 200B according to the present embodiment.

  Referring to FIG. 7, television 200B includes a memory 201, a display 202, a button 204, a communication interface 205, a speaker 207, a sensor 209, and a CPU 210.

  The memory 201 can be realized in the same manner as the memory 101 of the home controller 100. The memory 201 stores a control program executed by the CPU 210, power consumption of the television 200B, a command input to the television 200B, and the like.

  The display 202 is controlled by the CPU 210. More specifically, the display 202 displays a still image or a moving image based on data from a TV tuner or VRAM (Video RAM) (not shown).

  The button 204 is disposed on the surface of the television 200B. The television 200B may include a plurality of buttons 204 such as a determination key, a direction key, and a numeric keypad. The button 204 receives a command from the user and inputs the command to the CPU 210. Television 200B may include a remote control light receiving unit for receiving a signal from the remote controller.

The communication interface 205 transmits and receives data to and from the home controller 100 via the network 401 under the control of the CPU 210. As described above, the communication interface 205 transmits and receives data to and from the home controller 100 by using a wireless LAN, ZigBee (registered trademark), Bluetooth (registered trademark), wired LAN, or PLC.

  The speaker 207 outputs sound based on a command from the CPU 210. For example, the CPU 210 causes the speaker 207 to output sound based on the sound data.

  The clock 208 inputs the current date and time to the CPU 210 based on a command from the CPU 210.

  The sensor 209 measures the power consumption of the television 200B and transmits the power consumption to the CPU 210.

  The CPU 210 executes various types of programs stored in the memory 201, thereby executing information processing described in FIG. In other words, the processing in the television 200B is realized by each hardware and software executed by the CPU 210. Such software may be stored in the memory 201 in advance. The software may be stored in a storage medium and distributed as a program product. Alternatively, the software may be provided as a program product that can be downloaded by an information provider connected to the so-called Internet.

  Such software is read from the storage medium by using a reading device (not shown), or downloaded by using the communication interface 205 and temporarily stored in the memory 201. The CPU 210 stores the software in the form of an executable program in the memory 201 and then executes the program. Note that the storage medium and the program can be realized in the same manner as the recording medium and program according to the home controller 100.

<About household appliances 200A-200E>
Home appliances 200A to 200E according to the present embodiment have a sensor 209 for measuring power consumption and an input unit (button 204, remote control light receiving unit for receiving a command from the user), similarly to television 200B shown in FIG. And the communication interface 205 for transmitting the power consumption and the input command to the home controller 100.

<About inverter 200Z>
The power conditioner 200Z measures the power generated by the solar power generation device 200X, the stored or discharged power of the battery 200Y, and the trading power for the grid. Here, the power sales power (negative in the power purchase state), the generated power, the power consumption by the home appliances 200A to 200E, and the stored power (negative when discharging) satisfy the following relationship.

(Power sold) = (Power generated) − (Power consumed by home appliances 200A to 200E) − (Power stored)
The power conditioner 200Z transmits information indicating the power generated by the solar power generation device 200X, the stored or discharged power of the battery 200Y, and the power sold to the grid to the home controller 100 via the communication interface.

<Information Processing in Home Controller 100>
Next, information processing in home controller 100 according to the present embodiment will be described. Below, the case where the solar power generation screen is displayed is demonstrated. FIG. 8 is a flowchart showing a processing procedure of information processing in home controller 100 according to the present embodiment.

  More specifically, a process when the CPU 110 accepts an energy monitoring screen selection command will be described. In other words, the CPU 110 starts the following information processing with the selection instruction on the energy monitoring screen as a trigger.

  Referring to FIG. 8, CPU 110 determines whether data is received from home appliances 200A to 200E or power conditioner 200Z via communication interface 105 (step S102). CPU110 repeats the process from step S102, when data are not received from household appliance 200A-200E or the power conditioner 200Z (when it is NO in step S102).

  In the present embodiment, CPU 110 requests information indicating power consumption and failure from home appliances 200 </ b> A to 200 </ b> E via communication interface 105 when an instruction to select an energy monitoring screen is received. However, the CPU 110 sequentially receives information indicating power consumption or failure from the home appliances 200A to 200E via the communication interface 105 regardless of reception of the selection instruction of the energy monitoring screen, and stores the information in the power consumption table 101A. You may keep it.

  When CPU 110 receives data from home appliances 200A to 200E or power conditioner 200Z (YES in step S102), CPU 110 determines whether or not the data includes information indicating power consumption by home appliances 200A to 200E ( Step S104).

  CPU110 matches the information which shows the said power consumption with the information which shows the household appliances 200A-200E of a transmission source, when the said data contain the information which shows the power consumption by 200A-200E of household appliances (when it is YES in step S104). The data is stored in the power consumption table 101A of the memory 101 (step S106). At this time, the CPU 110 calculates the latest integrated power amount and the latest average integrated power amount, and updates the power consumption table 101A with the integrated power amount and the average integrated power amount.

  In step S106, CPU 110 determines that home appliances 200A to 200E are overused when home appliances 200A to 200E are not in failure and the integrated power amount of home appliances 200A to 200E is greater than the average integrated power amount. CPU 110 updates the state data of power consumption table 101A based on the determination result. However, CPU 110 may determine whether or not the integrated power amount is larger than the average integrated power amount in step S114, which will be described later, and update power consumption table 101A.

  As a modification, the average integrated power amount corresponding to each of the home appliances 200A to 200E is stored in the memory 101, and the CPU 110 stores the integrated power consumption amount of each of the home appliances 200A to 200E and the average integrated power amount corresponding to the home appliance. If the integrated power consumption amount of any home appliance is equal to or greater than the average integrated power amount, the home appliance may be determined to be overused.

  As a further modification, the normal power consumption corresponding to each of the home appliances 200A to 200E is stored in the memory 101, and the CPU 110 compares the power consumption of each of the home appliances 200A to 200E with the normal power consumption corresponding to the home appliance. As a result of the comparison, when the power consumption is equal to or higher than the normal power consumption, it may be determined that the household appliance is overused.

  In step S106, CPU 110 determines that home appliances 200A to 200E are in use when home appliances 200A to 200E are not out of order and are not overused, and power consumption of home appliances 200A to 200E is greater than standby power. CPU 110 updates the state data of power consumption table 101A based on the determination result. However, the CPU 110 may update the power consumption table 101A by determining whether or not the power consumption is larger than the standby power in step S114 described later.

  When the data does not include information indicating the power consumption by the home appliances 200A to 200E, the CPU 110 includes information indicating that the home appliances 200A to 200E are out of order (in the case of NO in step S104). ), The state data of the power consumption table 101A of the memory 101 is updated based on the information (step S108).

  CPU110 judges whether the information which shows power consumption or a failure was received from all the household appliances 200A-200E (step S110). CPU110 repeats the process from step S102, when there exists household appliances 200A-200E which have not received the information which shows power consumption or a failure yet (when it is NO in step S110).

  CPU110 judges the state regarding each of household appliances 200A-200E with reference to the power consumption table 101A, when the information which shows power consumption or a failure is received from all the household appliances 200A-200E (when it is YES in step S110). (Step S114). More specifically, CPU 110 refers to the state table of power consumption table 101A for each of home appliances 200A to 200E and determines whether or not a failure has occurred. CPU 110 refers to power consumption table 101 </ b> A for each of home appliances 200 </ b> A to 200 </ b> E that has not failed, and determines whether or not the accumulated power consumption is greater than the average accumulated power consumption. That is, the CPU 110 refers to the power consumption table 101A for each of the home appliances 200A to 200E that have not failed, and determines whether or not it is overused.

  CPU110 judges whether it is in use about each of the household appliances 200A-200E which are not out of order and are not overused. That is, CPU 110 determines whether or not the power consumption is greater than standby power (a predetermined value greater than standby power).

  The CPU 110 reads the floor plan 101D from the memory 101. CPU110 displays the images 120a-120d which show the state of the household appliances 200A-200E on the touch panel 106 in the position of the household appliances 200A-200E in a floor plan as a household appliance monitoring screen (step S116). CPU 110 transmits a home appliance monitoring screen to television 200 </ b> B via communication interface 105.

  CPU 110 waits for an instruction to select any of home appliances 200A to 200E via touch panel 106 or button 104 (step S118). CPU110 repeats the process from step S118, when a selection command is not received (when it is NO in step S118).

  CPU110 displays the graph which shows transition of the power consumption of the selected household appliance on display 102, as shown in FIG.6 (d), when a selection command is received (when it is YES in step S118) (step S118). S120). In the present embodiment, CPU 110 reads comments corresponding to home appliances and states from comment table 101B. CPU 110 causes touch panel 106 to display a comment. For example, the CPU 110 reads the usage time of the home appliances 200A to 200E from the power consumption table 101A and causes the touch panel 106 to display the text “XX hours in use” based on the usage time.

  CPU110 transmits the graph and transition which show transition of the power consumption of the selected household appliance to television 200B via communication interface 105. FIG.

  CPU 110 waits for a display end command via touch panel 106 or button 104 (step S122). When the “close” or “return” button on touch panel 106 is pressed (YES in step S122), CPU 110 ends the display of the graph and repeats the processing from step S102. CPU110 repeats the process of step S122, when a display end command is not pressed down (when it is NO in step S122).

<Information processing on TV 200B>
Next, information processing in television 200B according to the present embodiment will be described. FIG. 9 is a flowchart showing a processing procedure of information processing in television 200B according to the present embodiment.

  Referring to FIG. 9, CPU 210 determines whether a home appliance monitoring screen is received from home controller 100 via communication interface 205 (step S202). CPU210 repeats the process from step S202, when the household appliance monitoring screen is not received (when it is NO in step S202).

  CPU210 displays a household appliance monitoring image on the display 202, when a household appliance monitoring screen is received (when it is YES in step S202) (step S204). That is, the CPU 210 causes the display 202 to display a floor plan of a house or office. At the same time, the CPU 210 causes the display 202 to display images indicating the states of the home appliances 200A to 200E at the positions of the home appliances 200A to 200E in the floor plan. CPU 210 receives a display command for displaying a detailed screen from the user via button 204 or via a remote controller and a remote control light receiving unit (not shown), that is, a command for selecting household appliances 200A to 200E on which usage states are displayed. (Step S206).

  CPU210 repeats the process from step S206, when a selection command is not received (when it is NO in step S206). When CPU 210 receives the selection command (YES in step S206), CPU 210 uses home screen 100 to display the detailed screen of home appliances selected by home controller 100 (for example, consumption of home appliances 200A to 200E corresponding to the conditions) A graph indicating the transition of power is requested (step S208).

  CPU210 judges whether the graph and transition comment which show transition of the power consumption of household appliances 200A-200E applicable to conditions were received from the home controller 100 via the communication interface 205 (step S210). CPU210 repeats the process from step S210, when the graph and transition which show transition of the power consumption of the household appliances 200A-200E applicable to conditions from the home controller 100 are not received (when it is NO in step S210).

  When the CPU 210 receives a graph and a comment indicating the transition of the power consumption of the home appliances 200A to 200E corresponding to the condition from the home controller 100 (in the case of YES in step S210), as illustrated in FIG. The display 202 displays a graph indicating the transition of power consumption and a comment (step S212).

  CPU 210 waits for a display end command from the user via button 204 or via a remote controller and remote control light receiving unit (not shown) (step S214). For example, when “close” or “return” button is selected (YES in step S214), CPU 210 ends the graph display and repeats the processing from step S202. CPU210 repeats the process of step S214, when a display end command is not input (when it is NO in step S214).

[Embodiment 2]
Next, a second embodiment of the present invention will be described. In the network system 1 according to the first embodiment described above, the home appliances 200 </ b> A to 200 </ b> E measure the power consumption and transmit the power consumption (and failure information) to the home controller 100. On the other hand, in network system 1B according to the present embodiment, each of home appliances 200A to 200E does not transmit power consumption to home controller 100. That is, instead of the home appliances 200A to 200E, a power consumption measuring device having a communication function attached to an outlet for supplying power to the home appliances 200A to 200E measures the power consumption of each of the home appliances 200A to 200E. Information indicating power is transmitted to the home controller 100.

<Overall configuration of network system>
The overall configuration of network system 1B according to the present embodiment will be described. FIG. 10 is an image diagram showing an overall configuration of network system 1B according to the present embodiment.

  Referring to FIG. 10, network system 1B according to the present embodiment is installed in, for example, a house or an office. The network system 1B includes an air conditioner 200A installed in the living room, a television 200B installed in the living room, a curtain opening / closing device 200C installed in the living room, a refrigerator 200D installed in the kitchen, and a dining room. Household appliances (electric equipment) such as the light 200E. The network system 1B includes a solar power generation device 200X, a battery 200Y, and a power conditioner 200Z for controlling them.

  In network system 1B according to the present embodiment, communication device 400A for air conditioner 200A is installed between air conditioner 200A and the outlet of air conditioner 200A. In other words, communication device 400A is plugged into an outlet of air conditioner 200A, and adapter 250A of air conditioner 200A is plugged into communication device 400A. Similarly, a communication device 400C for the curtain opening / closing device 200C is installed between the curtain opening / closing device 200C and the outlet of the curtain opening / closing device 200C. In other words, the communication device 400C is inserted into the outlet of the curtain opening / closing device 200C, and the adapter 250C of the curtain opening / closing device 200C is inserted into the communication device 400C. Communication device 400D for refrigerator 200D is installed between refrigerator 200D and the outlet of refrigerator 200D. In other words, the communication device 400D is plugged into the outlet of the refrigerator 200D, and the adapter 250D of the refrigerator 200D is plugged into the communication device 400D. A communication device 400E for the light 200E is installed between the light 200E and the outlet of the light 200E. In other words, the communication device 400E is plugged into the outlet of the light 200E, and the adapter 250E of the light 200E is plugged into the communication device 400E.

  The network system 1B includes a home controller 100 for controlling home appliances 200A to 200E, a solar power generation device 200X, a battery 200Y, a power conditioner 200Z for controlling them, and the like. The home controller 100 can perform data communication with the home appliances 200A to 200E, the solar power generation device 200X, the battery 200Y, and the power conditioner 200Z for controlling them via a wired or wireless network 401. The home controller 100 uses, for example, a wireless LAN, ZigBee (registered trademark), Bluetooth (registered trademark), wired LAN, or PLC as the network 401. The home controller 100 may be portable, may be detachable from a base placed on a table, or may be fixed to a wall of a room.

  Compared with network system 1B according to the first embodiment, network system 1B according to the present embodiment has home controller 100 acquiring power consumption by home appliances 200A to 200E via communication devices 400A to 400E. Is different. Other configurations are the same as those in the first embodiment, and thus description thereof will not be repeated. In detail, in this Embodiment, the home controller 100 does not receive the information which shows that the household appliances 200A-200E are out of order.

<Other embodiments>
It goes without saying that the present invention can also be applied to a case where it is achieved by supplying a program to the home controller 100, the home appliances 200A to 200E, other mobile phones, and the like. Then, a storage medium storing a program represented by software for achieving the present invention is supplied to the system or apparatus, and the computer (or CPU or MPU) of the system or apparatus stores the program code stored in the storage medium It is possible to enjoy the effects of the present invention also by reading and executing.

  In this case, the program code itself read from the storage medium realizes the functions of the above-described embodiment, and the storage medium storing the program code constitutes the present invention.

  Further, by executing the program code read by the computer, not only the functions of the above-described embodiments are realized, but also an OS (operating system) running on the computer based on the instruction of the program code However, it is needless to say that a case where the function of the above-described embodiment is realized by performing part or all of the actual processing and the processing is included.

  Further, after the program code read from the storage medium is written to a memory provided in a function expansion board inserted into the computer or a function expansion unit connected to the computer, the function expansion is performed based on the instruction of the program code. It goes without saying that the CPU or the like provided in the board or the function expansion unit performs part or all of the actual processing and the functions of the above-described embodiments are realized by the processing.

  The embodiment disclosed this time should be considered as illustrative in all points and not restrictive. The scope of the present invention 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.

  1, 1B network system, 100 home controller, 101, 201 memory, 101A power consumption table, 101B comment table, 101C display screen, 101D floor plan, 120A, 120a to 120d, 120a, 120b, 120c, 120d image, 200A to 200E Home appliance, 200X solar power generation device, 200Y battery, 200Z power conditioner, 209 sensor, 250A, 250C, 250D, 250E adapter, 400A, 400A-400E, 400C, 400D, 400E communication device, 401 network, 402 power line.

Claims (18)

A communication interface for receiving the power consumption of multiple devices;
A memory for storing the power consumption of each of the plurality of devices;
A controller that determines a state of the device based on the power consumption of each of the plurality of devices, and outputs information indicating the state of the device in association with each of the plurality of devices. The processor is
A first indicating that any of the plurality of devices is in use in association with any of the plurality of devices when the power consumption of any of the plurality of devices is equal to or greater than a first threshold. Output an image,
When the power consumption of any of the plurality of devices is less than the first threshold, the second indicating that any of the plurality of devices is not used in association with any of the plurality of devices. The controller according to claim 1, which outputs an image of   The controller according to claim 2, wherein the first threshold is set corresponding to each of the plurality of devices. The processor is
When the power consumption of any of the plurality of devices is greater than or equal to a first threshold value, the first image is output in association with any of the plurality of devices,
When the power consumption of any of the plurality of devices is equal to or greater than a second threshold value that is less than the first threshold value and smaller than the first threshold value, Output an image of
The controller according to claim 1, wherein when the power consumption of any of the plurality of devices is less than the second threshold, a third image is output in association with any of the plurality of devices. The first threshold is set corresponding to each of the plurality of devices,
The controller according to claim 4, wherein the second threshold value is set corresponding to each of the plurality of devices. The processor is
Obtaining the accumulated power consumption of each of the plurality of devices;
When the accumulated power consumption amount of any of the plurality of devices is equal to or greater than a third threshold, any one of the plurality of devices is overused in association with any of the plurality of devices. The controller according to claim 2, wherein the controller outputs a fourth image to be displayed.   The controller according to claim 6, wherein the third threshold value is set corresponding to each of the plurality of devices. The memory stores a correspondence relationship between each of the plurality of devices and a room in which the device is disposed,
The processor is
The information indicating the state of each of the plurality of devices is output in association with the room in which the devices are arranged by referring to the correspondence relationship in the memory. Controller described in. The memory is
Storing a floor plan representing a plurality of rooms in which the plurality of devices are arranged, and positions of the plurality of devices in the floor plan;
9. The processor according to claim 1, wherein the processor refers to the memory and outputs information indicating the states of the plurality of devices in association with the positions of the plurality of devices in the floor plan. The controller according to item 1. A display,
The processor is
The controller according to claim 1, wherein information indicating a state of the plurality of devices is displayed on the display. The communication interface can communicate with an external display,
The controller according to any one of claims 1 to 10, wherein the processor causes the external display to display information indicating a state of the plurality of devices via the communication interface. The processor is
12. The information processing apparatus according to claim 1, wherein an instruction for selecting one device from the plurality of devices is received, and information indicating a transition of power consumption of the one device is output by referring to the memory. Controller described in the section. The memory stores a message in association with the device and the state,
The processor is
13. The device according to claim 1, wherein a command for selecting one device from the plurality of devices is received, and the message corresponding to the one device and a state corresponding to the one device is output. Controller described in the section. The processor is
The controller according to claim 1, wherein the controller receives power consumption from each of the plurality of devices via the communication interface. The processor is
Via the communication interface, receiving information indicating that any of the plurality of devices is in failure from any of the plurality of devices;
The controller according to claim 14, wherein a fifth image indicating that any one of the plurality of devices is malfunctioning is output in association with any one of the plurality of devices. The processor is
The controller according to claim 1, wherein the power consumption is received from a plurality of communication devices for measuring power consumption of each of the plurality of devices via the communication interface. A communication interface for receiving the power consumption of multiple devices;
A memory for storing the power consumption of each of the plurality of devices;
A processor that determines the state of the device based on the power consumption of each of the plurality of devices, and outputs information indicating the state of the device in association with each of the plurality of devices;
The processor is
A first indicating that any of the plurality of devices is in use in association with any of the plurality of devices when the power consumption of any of the plurality of devices is equal to or greater than a first threshold. Output an image,
When the power consumption of any of the plurality of devices is less than the first threshold, the second indicating that any of the plurality of devices is not used in association with any of the plurality of devices. Output an image of
The processor is
Obtaining the power consumption of each of the plurality of devices;
When the acquired power consumption of any of the plurality of devices is equal to or greater than a third threshold, any of the plurality of devices is overused in association with any of the plurality of devices. A controller that outputs the image shown. An information processing method in a controller including a communication interface, a memory, and a processor,
The processor receiving power consumption of a plurality of devices via the communication interface;
The memory storing the power consumption of each of the plurality of devices;
The processor determining a state of the device based on the power consumption of each of the plurality of devices;
And a step of outputting information indicating a state of the device in association with each of the plurality of devices.

Images