JP2014036466A - Power management device and power management system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To switch the operational mode of a home electric appliance to achieve the target of peak-cut control without damaging the function of the home electric appliance as much as possible.SOLUTION: A power management device includes: a communication section for receiving the operation information and power information of a plurality of pieces of electrical equipment, and for transmitting an instruction; a power consumption data storage section for preliminarily storing power consumption in association with each operational state; a total power consumption calculation section for calculating the total power consumption of each piece of electrical equipment; and a cooperative operation control section for issuing an instruction to change the operational state of each piece of electrical equipment when the total power consumption exceeds an allowable power consumption. The total power consumption calculation section acquires a post-transition total power consumption based on the post-transition operational state in response to the change of the operational state of any piece of electrical equipment. The cooperative operation control section extracts the combination of the operational states of the respective pieces of electrical equipment whose post-transition total power consumption falls in the allowable power consumption, and when the plurality of ways of combinations are extractable, controls the successive switching of the plurality of ways of combinations.

Description

  The present invention relates to a power management apparatus and a power management system, and more specifically, a power management apparatus that performs control to keep power consumption of the entire system below a predetermined value while maintaining the functionality of an electrical device to be managed as much as possible. And to a power management system.

In recent years, from the viewpoint of environmental protection and energy problems, efforts have been made to raise awareness of energy saving (hereinafter also referred to as “energy saving”) of electrical equipment (mainly home appliances) used in the home. Energy saving is intended to reduce energy consumption by efficiently using energy or suppressing the consumption of excess energy. As a system for supporting such efforts, HEMS (Home Energy Management System) has been put into practical use. By using such HEMS, home power management and power control can be performed more easily.
As one mode for suppressing the consumption of excess energy, control (hereinafter also referred to as peak cut control) for suppressing the power consumption of the entire system to a predetermined target value or less can be considered. The target value may be set by the user himself / herself in order to save energy. In addition, a target value may be set in response to a power saving request from a power company that supplies power.

  Several specific methods related to peak cut control have been proposed. The first technique is to store past life patterns, that is, usage patterns of household electrical appliances in advance, and predict and control usage patterns of each household electrical appliance based on the stored patterns, thereby making the convenience and comfort as much as possible. Peak cut control is performed so as not to impair it. As a method of controlling the device, not only on / off control but also a method of reducing the output of the device is used (for example, see Patent Document 1).

The second method is to apportion the power usage according to the room where the setting of temperature and illuminance is high and the room where the setting is low, and perform peak cut control of each room within the range of the apportioned electric power usage. Yes (see, for example, Patent Document 2).
The third method is to determine, for example, which of the lighting equipment and the air conditioning equipment is mainly controlled according to external conditions such as temperature and natural light, and to perform peak cut control according to the external conditions. (For example, refer to Patent Document 3).
In the fourth method, the order of devices that may stop the operation of the home appliances or reduce the power consumption is determined in advance, and the operation of each home appliance is controlled according to the order during peak cut control ( For example, see Patent Document 4).

JP 2001-54176 A JP 2009-204188 A JP 2009-240054 JP 2009-130973 A JP 2009-130974 A

As described above, various methods for executing peak cut control without impairing comfort as much as possible have been proposed, but each method has advantages and disadvantages.
The predictive control according to the first method may ensure comfort, but energy is wasted if the behavior at peak cut does not match the predicted pattern. In the second method, it is necessary to apportion the power consumption for each room in advance, but even if there is a surplus in the power that can be used in one room, the power that can be used in other rooms is limited to the apportioned power. The In the third method, a device that reduces power consumption is influenced by external conditions, and the function of the device may be impaired. In the fourth method, the order in which the power consumption can be reduced is fixedly determined in advance, so that home appliances to which a high priority is assigned are likely to lose their functions.

  In general, home appliances can set various operation states (operation modes) with different power consumption. However, since the number of operation modes is limited, it is not always possible to find an operation mode with optimum power consumption for peak cut control. . For example, when a certain household electrical appliance has two types of operation modes, a normal mode and a power saving mode, simply switching from the normal mode to the power saving mode will stop the household electrical appliance if the peak cut control target is not met. You may not get.

  The present invention has been made in consideration of the above circumstances, and a power management device that switches the operation mode of home appliances so that the target of peak cut control can be achieved without impairing the functions of the home appliances as much as possible. A power management system is provided.

The present invention communicates with a plurality of electric devices, receives operation information indicating an operation state of each electric device and power information related to power consumption of each electric device, and transmits an instruction to change the operation state of the electric device. A communication unit, a power consumption data storage unit that stores power consumption in advance in association with operating states that can be taken by each electrical device, a total power consumption calculation unit that calculates total power consumption as the total power consumption of each electrical device, A comparison unit that compares whether or not the total power consumption exceeds a predetermined allowable power consumption, and an instruction to change the operating state of each electrical device when the total power consumption exceeds the allowable power consumption A cooperative operation control unit that controls the operation, and the total power consumption calculation unit operates in response to the fact that the communication unit has received operation information notifying that the operation state of any of the electrical devices has changed. The total power consumption after transition based on the state is acquired, and the cooperative operation control unit causes each electrical device to transition or stop to an operation state with lower power consumption when the total power consumption after transition exceeds the allowable power consumption. In such a case, a combination of operation states of each electrical device is extracted so that the total power consumption after the transition falls within the allowable power consumption, and if a plurality of combinations can be extracted, the operation state of each electrical device is changed. Provided is a power management apparatus which controls to repeatedly switch an instruction of a plurality of combinations by repeatedly issuing instructions over time.
Moreover, the power management system provided with the said power management apparatus is provided.

  In the power management apparatus and the power management system of the present invention, the cooperative operation control unit, when the total power consumption after the transition exceeds the allowable power consumption, when each electrical device is transitioned or stopped to the operation state of lower power consumption If the combination of the operating states of each electrical device such that the total power consumption after the transition is within the allowable power consumption is extracted and multiple combinations can be extracted, an instruction to change the operating state of each electrical device is issued. Since control is performed so that the plurality of combinations are sequentially switched over time, the function can be controlled such that only a specific home appliance is not impaired.

  Further, for example, a plurality of combinations may be extracted so that the operation of a certain home electric appliance is stopped in a certain combination and the other home electric appliance is operated in another combination. If these combinations are sequentially switched, the home appliance operates even intermittently. Therefore, it is possible to control the power consumption of each home appliance more finely than in the case where the sequential switching of the combinations is not performed, and to bring the total power consumption closer to the allowable power consumption.

This invention will be described more specifically.
In the present invention, the power management system manages the operation and power consumption of an electric device installed and used in a house such as a house or office. The specific aspect is HEMS, for example. The power management device is a device that controls each electrical device as the core. In an embodiment described later, the power management apparatus corresponds to a HEMS controller.
Each electrical device is connected to the power management apparatus by communication, and operates in response to an instruction from the power management apparatus as well as an operation from the user.
Moreover, about a communication part, regardless of a radio | wireless and a wire, regardless of a physical structure, and a communication protocol are not ask | required.

It is a block diagram which shows the whole structure of the power management system 11 by embodiment of this invention. It is a block diagram which shows the hardware constitutions of the HEMS controller by embodiment of this invention. It is an external view of the wattmeter by embodiment of this invention. It is a block diagram which shows the hardware constitutions of the wattmeter by embodiment of this invention. It is explanatory drawing which shows an example of the data which the power consumption data storage part by embodiment of this invention stores. It is 1st explanatory drawing which shows an example of the procedure which determines the operation mode of each household appliance in peak cut control by embodiment of this invention. It is 2nd explanatory drawing which shows an example of the procedure which determines the operation mode of each household appliance in peak cut control by embodiment of this invention. It is 3rd explanatory drawing which shows an example of the procedure which determines the operation mode of each household appliance in peak cut control by embodiment of this invention. It is explanatory drawing which shows the combination of each operation mode extracted in the procedure shown to FIGS. It is a flowchart which shows the process order of the peak cut control which the cooperative operation control part which concerns on this invention performs. FIG. 11 is a graph showing a state in which the cooperative operation control unit according to the present invention performs control so as to change the combination of the operation states of the electric devices and change over them sequentially with time. It is a graph which shows transition of the power consumption when the dishwasher by the embodiment of this invention and a washing dryer operate | move by switching a series of operation modes. It is a graph which shows an example of the operation | movement at the time of peak cut control of the dishwasher and washing dryer shown in FIG.

Hereinafter, preferred embodiments of the present invention will be described.
The total power consumption calculation unit refers to the power consumption data storage unit in response to operation information indicating that the operation state of any of the electrical devices changes, and based on the power consumption associated with the operation state after the transition You may make it acquire the total power consumption after transfer. In this way, the total power consumption after the transition is estimated at the time when the operation information is received even before the operation state of the electric device actually changes, and the total power consumption after the transition is within the allowable power consumption. It is possible to extract a combination of operating states of each electric device.

  Alternatively, it further includes a total power consumption measuring unit that measures the total power consumption of a system that manages the power in the house, and the total power consumption calculating unit responds to operation information indicating that the operating state of any of the electrical devices changes. Then, the total power consumption measured by the total power consumption measuring unit after the transition may be referred to obtain the total power consumption after the transition. If it does in this way, the total power consumption after the operation state of an electric equipment will transfer will be measured by the said total power consumption measurement part, and after transfer, the total power consumption after a transition will be settled in the said permissible power consumption. It is possible to extract a combination of operating states of each electric device.

  In addition, each electrical device and / or each operation state is given in advance an attribute of either a steady operation type that operates constantly or a temporary operation type that operates temporarily, and the cooperative operation control unit includes: When the total power consumption after the transition exceeds the allowable power consumption due to a change in the operation state of the temporary operation type electrical device, or when the operation state is shifted to a lower power consumption operation state only for each steady operation type electrical device When the combination of the operating states of each electrical device is extracted such that the total power consumption after the transition falls within the allowable power consumption, and a plurality of combinations can be extracted, control is performed to change the operating state of each electrical device. May be. In this way, control is performed so that the total power consumption after the transition falls within the allowable power consumption by temporarily shifting to a lower power consumption state only for each electric device that is steadily operating. it can.

Further, among the temporary operation type electric devices, an electric device that operates by sequentially switching a series of operation states and / or a series of operation states is further given a sequential operation type attribute, and the cooperative operation control unit includes: If the total power consumption after the transition exceeds the allowable power consumption due to a change in the operating state of the sequential operation type electrical device, waiting for the transition of the operation state of any one of the sequential operation type electrical devices only In such a case, one combination of operation states of each electrical device is extracted so that the total power consumption after the transition is within the allowable power consumption, and the operation state of each electrical device is determined based on the extracted combination. You may control so that it may change with progress of time. In this way, it is possible to control so that the total power consumption after the transition falls within the allowable power consumption by delaying the switching of the operation state for only the sequentially-operating electric devices.
Preferred embodiments of the present invention include combinations of any of the plurality of embodiments shown here.

  Hereinafter, the present invention will be described in more detail with reference to the drawings. In addition, the following description is an illustration in all the points, Comprising: It should not be interpreted as limiting this invention.

<Configuration of power management system>
The indoor power management system according to the present embodiment includes a power management device, and the power management device manages power information related to power consumption in at least one electrical device. It should be noted that a solar power generation device (hereinafter also referred to as an external sunlight power generation device), a fuel cell, and the like may be managed, and in this case, the power management system according to the present embodiment may be used in addition to power consumption or Instead of power consumption, power information related to power generation may be managed.

  In the present specification, the power information is a concept including various information related to power consumption / power generation in a corresponding electric device (electric appliance).

  Hereinafter, a power management system including a plurality of electrical devices used in a house will be described as an example, but the present invention is not applied only to such a power management system. In other words, the present invention can be applied to any configuration as long as information regarding power consumption is measured using a power meter or the like.

  In this specification, the electric device is a concept including both a device that operates with electric power supplied from each unit and a device that generates electric power with some energy. Houses include houses and offices.

  FIG. 1 is a block diagram showing an overall configuration of a power management system 11 according to an embodiment of the present invention.

  As shown in FIG. 1, the power management system 11 according to the present embodiment generally manages the power in a house such as a house or office where electric devices that operate by receiving power supply from a power system are installed. To do. More specifically, the power management system 11 includes a plurality of home appliances as electric devices that consume power.

  In FIG. 1, although not limited to these, as home appliances, an air conditioner (air conditioner) 200A, a refrigerator 200B, an electric carpet 200C, a hot water washing toilet seat 200D, a dishwasher / dryer 200E, and a laundry installed in a house are used. A dryer 200F (these are also collectively referred to as “home appliance 200”) and the like are illustrated. Further, the power management system 11 may include an external solar power generation device (not shown) and a storage battery (not shown) that stores and discharges electric power as electric devices that generate electric power. Furthermore, you may receive supply of electric power from the vehicle-mounted storage battery at the time of a power failure including the vehicle-mounted storage battery (not shown) connected via the connection part only for EV charge. In this embodiment, each home appliance has an ID number for identification.

Furthermore, the power management system 11 is connected to a power system (commercial power provided by an electric power company) via a distribution board 300.
The distribution board 300 distributes electricity to each room and each outlet, and is provided with an amper breaker, an earth leakage breaker, and a circuit breaker so that no accident occurs due to overuse or earth leakage. The ampere breaker is automatically turned off when electricity exceeding a predetermined ampere flows. The earth leakage circuit breaker quickly detects an abnormality when the earth leakage occurs and turns off electricity. The circuit breaker is for protecting the safety of the branch circuit.
The distribution board 300 is provided with a wattmeter using an AC ammeter (CT sensor 305). CT sensor 305 measures the electric power consumed in the whole house. Further, the CT sensor 305 includes a communication module for data communication with the HEMS controller.

Furthermore, the power management system 11 includes power meters 400A to 400F with communication modules associated with the home appliance 200 (hereinafter, these power meters are collectively referred to as a power meter 400) and a HEMS controller 120 that is a power management device. (HEMS is an abbreviation for Home Energy Management System).
The HEMS controller 120 controls each home electric appliance so that the power consumption of the entire house is less than or equal to the allowable power consumption. The control is to coordinate the operation modes of the home appliances with each other so that power saving and operation of each home appliance are compatible. Details of the control will be described later.
The HEMS controller 120 can perform data communication with each home electric appliance 200 (200A to 200F) and the wattmeter 400 (400A to 400F) associated with each home electric appliance 200 via a wired or wireless network 401. It is.

Any network 401 can be used. In the case of a wired network, for example, Ethernet (registered trademark), PLC (Power Line Communications), or the like can be used as a physical layer and a data link layer (so-called physical dependency layer or lower layer) of the OSI basic reference model. However, it is not limited to this.
For a wireless network, for example, a wireless local area network (LAN), ZigBee (registered trademark), Bluetooth (registered trademark), or a red line communication system that conforms to the IEEE 802.11 standard can be used. Further, a plurality of communication methods may be combined.
Moreover, as an upper layer with respect to these so-called lower layers, for example, ZigBee (registered trademark), ECHONET Lite, KNX, Z-Wave, or the like can be used, but is not limited thereto.
The content exchanged on the network 401 includes power information, operation information, and instructions. The power information is data indicating the power consumption of each home appliance 200. The operation information is data indicating an operation state of each home appliance 200. The instruction is data for setting an operation state (operation mode) of each home appliance 200. The operation mode of each home appliance can be set by the user operating each home appliance 200, but the HEMS controller 120 can also set the operation mode by sending an instruction to each home appliance 200.

  The power meter 400 is associated with one of the home appliances 200, measures information regarding power consumption in the associated home appliance 200, and transmits the measured information to the HEMS controller 120 as power information. Typically, as the power meter 400, a power consumption measuring device that is disposed between the power line 402 and the power plug 250 (250A to 250F) of the home appliance 200 and measures the power consumption state is used. Each power meter transmits the measured power consumption to the HEMS controller 120. On the other hand, the home appliance 200 transmits operation information indicating the operation state of each home appliance to the HEMS controller 120 via the network 401.

The HEMS controller 120 corresponds to the power management apparatus of the present invention. When the CPU 121 included in the HEMS controller 120 receives power information from each wattmeter 400 and receives operation information from each home appliance 200, the operation information of each home appliance is associated with the power information, and the power consumption based on the results The data is stored in the hard disk 129 included in the HEMS controller 120 as data.
As a different aspect, the manufacturer and / or seller of each household electrical appliance provides power consumption in each operating state that the household electrical appliance can take as data, and the CPU 121 downloads the data and uses the estimated power consumption data. May be stored in the aforementioned hard disk.

  In the example shown in FIG. 1, six power meters 400 </ b> A to 400 </ b> F are connected to the power line 402. A power plug 250A of the air conditioner 200A is connected to the wattmeter 400A, and a power plug 250B of the refrigerator 200B is connected to the wattmeter 400B. A power plug 250C of the electric carpet 200C is connected to the wattmeter 400C, and a power plug 250D of the hot water washing toilet seat 200D is connected to the wattmeter 400D. Furthermore, a power plug 250E of the dishwasher 200E is connected to the wattmeter 400E, and a power plug 250F of the washing dryer 200F is connected to the wattmeter 400F. That is, the power meters 400A to 400F measure information regarding power consumption in the air conditioner 200A, the refrigerator 200B, the electric carpet 200C, the warm water washing toilet seat 200D, the dishwasher 200E, and the washing dryer 200F, respectively. As a modification, the power meter 400 may be built in each home appliance 200, and each home appliance 200 may transmit both operation information and power information to the HEMS controller 120.

Further, the HEMS controller 120 provides a user interface that presents to the user the power consumption / generation state in the power management system 11 and receives an instruction regarding power management in the power management system 11 from the user.
Next, the hardware and functional configuration of the HEMS controller 120, which is a main power management apparatus in configuring the power management system 11 shown in FIG. 1, will be described.

<HEMS controller 120>
First, the hardware configuration of the HEMS controller 120 will be described.
FIG. 2 is a block diagram showing a hardware configuration of the HEMS controller 120 according to the embodiment of the present invention.

  As shown in FIG. 2, the HEMS controller 120 includes a CPU (Central Processing Unit) 121 that is a processor, a memory 122, a display 123, a touch panel 124, and operation buttons 125. Furthermore, a communication interface 126, an output interface 127, an input interface 128, a hard disk 129, a speaker 131, and a clock 132 are included.

  The CPU 121 of the HEMS controller 120 is a processing entity that controls the entire processing in the HEMS controller 120, and provides various functions as a management device of the power management system 11 by executing a program stored in advance in the memory 122 or the like. That is, the CPU 121 accepts a user operation input from the touch panel 124 or the operation button 125. In response to these operations, processing instructed by the user operation is executed. Such an instruction includes an instruction related to operation / stop for the home appliance 200 and an instruction related to a change in the operation mode. Further, the CPU 121 causes the display 123 to display the current or past power management state.

  The memory 122 is realized by a RAM (Random Access Memory) that is a volatile storage device, a flash ROM (Flash Read-Only Memory) that is a nonvolatile storage device, and the like. Stores work data required for execution.

  The display 123 and the touch panel 124 are devices that provide a user interface. The display 123 presents display data received from the HEMS controller 120 to the user in accordance with a command from the CPU 121. The touch panel 124 receives an operation performed by the user.

  More specifically, the display 123 includes, for example, an LCD (Liquid Crystal Display) or an organic EL (Electro Luminescence) display, and displays an image on its display surface. The touch panel 124 detects a touch operation with a user's finger or the like, and outputs a coordinate value indicating a position where the touch operation is performed to the CPU 121. In the present embodiment, touch panel 124 is provided in association with the display surface of display 123. However, the HEMS controller 120 does not necessarily include a touch panel, and it is sufficient that various information can be presented to the user.

  The operation buttons 125 are input means for accepting user operations, and typically one or more are arranged on the surface of the HEMS controller 120. Typically, the operation button 125 includes a plurality of buttons and keys such as a determination button, a return button, a direction button, and a numeric keypad. When the operation button 125 accepts a user operation, the operation button 125 outputs information indicating the user operation to the CPU 121.

  The communication interface 126 performs data communication with the home appliance 200, the CT sensor 305, the wattmeter 400, and the like in accordance with a command from the CPU 121. More specifically, the communication interface 126 includes, as described above, Ethernet (registered trademark), PLC (Power Line Communications), wireless LAN (Local Area Network) compliant with the IEEE 802.11 standard, ZigBee (registered trademark), Bluetooth (registered trademark), each red line communication method, and the like are used.

  The output interface 127 mediates exchange of internal commands between the CPU 121 and the display 123. The input interface 128 mediates exchange of internal commands and / or signals between the touch panel 124 and / or the operation buttons 125 and the CPU 121.

The hard disk 129 stores various data necessary for information processing in the HEMS controller 120. Details of the various data will be described later.
Instead of the hard disk 129, semiconductor memory media such as flash memory, mask ROM, EPROM (Electronically Programmable Read-Only Memory), EEPROM (Electronically Erasable Programmable Read-Only Memory), IC (Integrated Circuit) card, CD-ROM (Compact Disc-Read Only Memory) and optical disc storage media such as DVD-ROM (Digital Versatile Disk-Read Only Memory), magneto-optical disc storage media such as MO (Magnetic Optical Disc) and MD (Mini Disc), FD ( Magnetic storage media such as Flexible Disk), magnetic tape, and cassette tape can be used.

  The speaker 131 is an audio device, and outputs audio according to a command from the CPU 121.

  The clock 132 is a time measuring unit, and responds to the CPU 121 with the current date and time according to a command from the CPU 121.

  Information processing in the HEMS controller 120 is realized by the CPU 121 executing a program in cooperation with peripheral hardware components. Generally, such a program is installed in advance in the memory 122 or the like.

  Such a program can be provided by being stored and distributed in an arbitrary storage medium. Alternatively, such a program can be provided by downloading from a server device (or other device) connected to the Internet or the like. That is, the program stored in the storage medium is read out, or the program is acquired by downloading from the server device and temporarily stored in the memory 122 or the like. The CPU 121 expands the program stored in the memory 122 into an executable format and then executes the program. Storage media for storing such programs include semiconductor memory media such as flash memory, mask ROM, EPROM, EEPROM, and IC card, optical disk storage media such as CD-ROM and DVD-ROM, and optical media such as MO and MD. Magnetic storage media such as magnetic disk storage media, FD, magnetic tape, cassette tape, etc. can be used.

  Furthermore, instead of installing the program in advance in the memory 122 or the like, the CPU 121 may read and execute a program stored in another system or apparatus.

  Furthermore, after a program read from a storage medium or the like is written to a memory or the like mounted on a function expansion board or function expansion unit mounted on the computer, it is stored in the function expansion board or function expansion unit according to the program. The functions according to the present embodiment may be realized by performing all or part of necessary processing by a mounted arithmetic unit (CPU or the like).

  Furthermore, the CPU 121 executes not only all the functions according to the present embodiment by executing the program, but also all or part of processing that requires an OS (operating system) executed on the computer according to the program. By performing the above, the function according to the present embodiment may be realized.

  When the functions according to this embodiment are realized by software as described above, the program itself read from the storage medium or the like, or the storage medium storing the program constitutes one embodiment of the present invention. Become.

  In this specification, the program includes not only a program that can be directly executed by the CPU 121 but also a program in a source program format, a compressed program, and an encrypted program.

Next, the functional configuration of the HEMS controller will be described. FIG. 1 shows a functional configuration inside the HEMS controller 120. The CPU 121 of the HEMS controller executes the above-described program, and provides the function of the HEMS controller shown in FIG. 1 in cooperation with the hardware resources shown in FIG.
As shown in FIG. 1, the HEMS controller includes a communication unit 141, a total power consumption calculation unit 143, an allowable power consumption holding unit 145, a comparison unit 147, a cooperative operation control unit 149, and a power consumption data storage unit 151 from a functional aspect. Prepare. Further, a power measurement control unit 153 may be provided.

The communication unit 141 performs communication with each wattmeter 400, the CT sensor 305, and each home appliance 200. Moreover, the power information and operation information of each household appliance 200 are received, and the instruction | indication which sets the operation mode of each household appliance 200 is transmitted.
The total power consumption calculation unit 143 is based on the operation information of each home appliance, the power consumption data stored in the hard disk 129 and / or the power information from each power meter 400, or the CT disposed on the distribution board 300 Based on the measurement result of the sensor 305, the power consumption value of the entire house is calculated.

The allowable power consumption holding unit 145 holds the value of allowable power consumption. The allowable power consumption is a value set as a target of the power consumption of the entire house. The allowable power consumption can be set to a value that the user considers preferable by using the display 123 and the touch panel 124. Alternatively, the value may be determined in accordance with a power saving request from a power company that manages the power system.
The comparison unit 147 compares whether or not the total power consumption exceeds the allowable power consumption and informs the cooperative operation control unit 149 of the result.

  The cooperative operation control unit 149 grasps the power consumption and operation state of each home appliance based on the power information and the operation information, and issues an instruction to set the operation mode of each home appliance 200. When a certain household electrical appliance 200 starts an operation in response to an instruction from the user or the operation mode is changed, the cooperative operation control unit 149 estimates the total power consumption based on the power consumption data stored in the hard disk 129. Then, it is determined whether or not the allowable power consumption is exceeded, and if it is determined that the allowable power consumption is exceeded, a combination of operation modes that reduces the power consumption of each home appliance 200 and keeps the total power consumption below the allowable power consumption is extracted. To do. When there are a plurality of combinations, control is performed so that the plurality of combinations are sequentially switched over time in a time-sharing manner in order to suppress a decrease in the function of each home appliance. By switching operation mode combinations over time, it is easy to generate intermediate power consumption that cannot be realized simply by continuing the combination of only one operation mode, and total consumption without leaving specific home appliances stopped. It becomes possible to keep the power within the allowable power consumption.

In addition, when there is a home appliance that temporarily operates and consumes a large amount of power for a limited period of time, the operation of the home appliance that is steadily operating only during that period, , Heating, operation) can be implemented in a flexible manner such that the frequency of switching the operation mode of each home appliance varies depending on the response speed.
Furthermore, as an example of a household appliance that operates temporarily, a washing / drying machine, for example, operates by switching a series of operation modes, but waits for the start of the next operation mode after completion of one of the operation modes. However, although the end time is later than usual, it is possible to obtain the same finish as usual through the same operation mode.
When the power measurement control unit 153 is provided, the power measurement control unit 153 sets various operation modes that can be taken by each home appliance, measures power consumption for each mode, and creates power consumption data. For example, in the case of an air conditioner, each operation mode (cooling / heating, set temperature, temperature difference from the surroundings, air volume) is set by switching over time, power consumption in each operation mode is measured, and power consumption data is stored It controls to store in the part 151.

<Watt meter 400>
FIG. 3 is an external view of a wattmeter 400 according to the embodiment of the present invention. Here, FIG. 3A shows a perspective view including the power socket 4001 of the power meter 400, FIG. 3B shows a side view of the power meter 400, and FIG. A perspective view including a power plug 4002 of the wattmeter 400 is shown.

  As shown in FIG. 3A to FIG. 3C, the wattmeter 400 is disposed so as to be interposed between a power socket for supplying power flowing through the power line 402 and a power plug of the home appliance 200. Is done. More specifically, as shown in FIG. 3A, a power socket 4001 for plug insertion is provided on one surface (front surface) of the wattmeter 400. On the other hand, as shown in FIGS. 3B and 3C, a power plug 4002 is provided on the back surface of the wattmeter 400 opposite to the front surface. A power plug of the home appliance 200 is inserted into the power socket 4001, and the power plug 4002 is inserted into a power socket (outlet / outlet) for supplying power via a power line 402 provided in the house.

  Since the wattmeter 400 is preferably as thin as possible, the width of the side surface is designed to be as small as possible.

  On the front side of the wattmeter 400, an LED 4041 and a setting button 4042 are further provided. The LED 4041 displays a data processing state in the wattmeter 400. More specifically, the LED 4041 varies the presence / absence of lighting and the presence / absence / cycle of blinking according to the data processing state. Note that the emission color may be changed instead of or in addition to the lighting and blinking display modes. The setting button 4042 is an input means for accepting a user operation. When operated by the user, an initial setting or the like in the wattmeter 400 is started.

  FIG. 4 is a block diagram showing a hardware configuration of power meter 400 according to the embodiment of the present invention.

  As shown in FIG. 4, in addition to the power socket 4001, the power plug 4002, the LED 4041, and the setting button 4042, the power meter 400 includes a pair of main wirings 4004 that electrically connect the power socket 4001 and the power plug 4002, and 4005, a shunt resistor 4003 inserted in the main wiring 4005, a power supply unit 4007, a power detection unit 4010, a communication module 4020, and an antenna 4030.

  The power detection unit 4010 detects the power flowing from the power plug 4002 to the power socket 4001. More specifically, the power detection unit 4010 includes a voltage input ADC (Analog to Digital Converter) 4011, a current input ADC 4012, a multiplier 4013, and a digital / frequency conversion unit 4014.

  Voltage input ADC 4011 is connected to main wirings 4004 and 4005 via wirings V1P and V1N, respectively. The voltage input ADC 4011 outputs a digital signal indicating a voltage (potential difference) generated between the main wirings to the multiplier 4013.

  The current input ADC 4012 is electrically connected to both ends of the shunt resistor 4003 inserted in the main wiring 4005 via the wirings V2P and V2N. The shunt resistor 4003 is a minute (several hundred micro Ω) resistor used for measuring a flowing current value. The current input ADC 4012 outputs a digital signal indicating the current value of the current flowing through the shunt resistor 4003 to the multiplier 4013.

  The multiplier 4013 multiplies the digital signal (voltage value) from the voltage input ADC 4011 by the digital signal (current value) from the current input ADC 4012, and a value obtained as a result (power consumption / unit: W or kW). Is output to the digital / frequency converter 4014.

  The digital / frequency converter 4014 converts the digital signal from the multiplier 4013 into a frequency signal, and outputs the resulting frequency signal to the communication module 4020.

  The power supply unit 4007 supplies power to each component of the power meter 400. The power supply unit 4007 is connected to the main wirings 4004 and 4005, and uses part of the power flowing from the power plug 4002 to the power socket 4001 as power for operating the power meter 400. The power supply unit 4007 converts the AC power into DC power, and then supplies the DC power to the power detection unit 4010 and the communication module 4020.

  The communication module 4020 transmits a radio signal indicating the power consumption in the electric device connected to the power socket 4001 calculated by the power detection unit 4010 via the antenna 4030. More specifically, the communication module 4020 includes a CPU 4021, a ROM 4022, a RAM 4023, a GPIO (General Purpose Input / Output) 4024, and a wireless RF (Radio Frequency) unit 4025.

  The GPIO 4024 receives the frequency signal input from the digital / frequency conversion unit 4014 and outputs information on the frequency signal to the CPU 4021.

  The CPU 4021 converts the frequency signal information from the GPIO 4024 according to a predetermined logic, and outputs the result to the wireless RF unit 4025. The wireless RF unit 4025 generates a wireless signal by modulating a carrier wave based on a data conversion result from the CPU 4021. A radio signal generated by the radio RF unit 4025 is transmitted to the HEMS controller via the antenna 4030.

  The CPU 4021 implements the processing as described above by executing a program stored in the ROM 4022 in advance. The RAM 4023 stores work data necessary for the CPU 4021 to execute the program.

<Power information>
The power meter 400 basically measures the power consumption (unit: W or kW) consumed by the connected electrical device. By integrating the power consumption over a predetermined time, the power consumption amount (unit: Wh or kWh) of the electric device is calculated.

  The HEMS controller 120 can cause the display 123 to display both the power consumption and the power consumption of each electric device. Further, a plurality of electric devices are grouped and the power consumption and power consumption for the entire group are displayed.

  Therefore, for example, the following is an implementation example of the power information about the corresponding home appliance 200 transmitted from the power meter 400 to the HEMS controller 120 (however, it is not limited to the following example).

  (1) The power meter 400 measures the power consumption in the home appliance 200 every predetermined cycle (for example, every 5 seconds), and transmits the measured power consumption as power information at the same transmission cycle as the measurement cycle.

  (2) The power meter 400 measures the power consumption in the home appliance 200 every predetermined cycle (for example, every 5 seconds), and is measured between the previous transmission and the current transmission at a transmission cycle longer than the measurement cycle. The plurality of power consumptions are transmitted as power information.

  (3) The wattmeter 400 measures the power consumption in the home appliance 200 every predetermined period (for example, every 5 seconds), and is measured between the previous transmission and the current transmission at a transmission period longer than the measurement period. The average power consumption obtained by averaging the plurality of power consumptions is transmitted as power information.

  (4) In (2) or (3), a power consumption amount obtained by integrating a plurality of power consumptions measured from the previous transmission to the current transmission is added to the power information and transmitted. Furthermore, you may add the average value, minimum value, maximum value, etc. of some power consumption.

  Although the time information acquired by the wattmeter 400 by some means may be added to the power information, generally, when the HEMS controller 120 receives the power information from each wattmeter 400, the time at that time is clocked. It is acquired from 132 and stored in the hard disk 129 in association with the received power information.

  An arbitrary protocol can be adopted for exchanging power information between the HEMS controller 120 and the power meter 400. Typically, a configuration is adopted in which the power meter 400 broadcasts a packet including a measurement result of itself and notifies the HEMS controller 120 of the packet. However, the HEMS controller 120 may periodically poll each power meter 400.

<Power consumption data>
The power consumption data storage unit 151 stores in advance power consumption associated with operating states that can be taken by each electrical device.
FIG. 5 is an explanatory diagram showing an example of data stored in the power consumption data storage unit according to the embodiment of the present invention. Each of the tables in FIGS. 5A to 5F corresponds to the air conditioner 200A, the refrigerator 200B, the electric carpet 200C, the hot water washing toilet seat 200D, the dishwasher 200E, and the washing dryer 200F shown in FIG. 1, respectively.
For example, FIG. 5A is an example of power consumption data indicating the power consumption in each operation mode of the air conditioner 200A. Looking at cooling, when the outside air temperature humidity is 27 ° C and 80%, the power consumption in each operation mode when the air volume is set in the four stages of static, fine, weak and strong within the set temperature range of 22 to 28 ° C. Stored. In the “No.” column at the left end, for convenience, each operation mode is distinguished from other modes. For cooling, numbers “1e” to “1A” are assigned to the respective operation modes. This number is used for specifying each mode in the description of the specification. Furthermore, the power consumption when the air conditioner is stopped is stored.

  These power consumptions may be data stored and stored by an air conditioner manufacturer or seller. Alternatively, in the case of the configuration including the power measurement control unit 153, the power measurement control unit 153 collects the operation information of the air conditioner and the power information (power consumption) from the power meter 400A during the period in which the air conditioner 200A is operating. Specifically, the operation information is information such as an operation mode such as heating, cooling, and dehumidification, a set temperature, an air volume, and an outside air temperature humidity used by the air conditioner for temperature control. Further, the power measurement control unit 153 preferably performs statistical processing such as averaging the collected data, and stores the power consumption data corresponding to each operation mode in the power consumption data storage unit 151 or has already been stored. Update the data being stored.

  As a different mode, the power measurement control unit 153 switches and sets the operation mode of the air conditioner (operation mode such as heating, cooling, and dehumidification, set temperature, and air volume) over time, collects the operation information at that time, and collects the power meter Power information in each operation mode is collected from 400A. Then, the collected power consumption data in each operation mode is stored in the power consumption data storage unit 151 or the data already stored is updated.

  Similarly, power consumption data is also stored in the power consumption data storage unit 151 for other home appliances. Unlike the air conditioner 200A, the refrigerator 200B, the electric carpet 200C, and the warm water washing toilet seat 200D, the dishwasher 200E has predetermined different operation modes as a series of operations, and the operation proceeds by sequentially switching these operation modes. . That is, the operation modes of “washing”, “rinsing”, and “drying” proceed as a series. The washing water heating operation is performed during the “washing” and “rinsing” operation modes. Further, for the washing / drying machine 200F, operation modes of “washing”, “rinsing”, “dehydration”, and “drying” proceed as a series. In principle, a series of operation modes cannot be switched or skipped simply because peak cut control is performed.

<Peak cut control-Operation mode determination of each home appliance>
FIG. 6 is a first explanatory diagram illustrating an example of a procedure for determining an operation mode of each home appliance in peak cut control. It is assumed that the allowable power consumption is set to 1900W.
In FIG. 6, before the start of peak cut control, the total power consumption of each household electrical appliance 200 is in a state equal to or less than the allowable power consumption. That is, the air conditioner 200A is air-cooled with a power consumption of 345 W (operation mode is 1 v), and the refrigerator 200B is operated with a power consumption of 114.3 W (operation mode is 2 e). The electric carpet 200C stops when the power consumption is zero W (operation mode is 3a), and the hot water washing toilet seat 200D operates at a power consumption of 126W (operation mode is 4f). Furthermore, the dishwasher 200E is drying at a power consumption of 900 W (operation mode is 5 g), and the washing dryer 200F is dehydrating at a power consumption of 300 W (operation mode is 6d) (see “Peak Cut” in FIG. 6). Refer to “Before Control”.) Before starting the peak cut control, each home appliance 200 operates in the operation mode set by the user, and the cooperative control by the HEMS controller 120 is not performed.

  When the laundry dryer 200F is dehydrated, the operation mode shifts to the next drying. At this time, operation information indicating that the operation mode of the washing / drying machine 200F shifts to 6e is transmitted. When this operation information is received, the CPU 121 of the HEMS controller 120 refers to the power consumption data storage unit 151 and calculates the total power consumption when the operation mode of the washing / drying machine 200F shifts to 6e ("" in FIG. 6). Refer to “Guide after transition to operation mode 6e”). The total power consumption at this time is calculated by the CPU 121 based on the power consumption when the operation mode in FIG. 6F is 6e, and is not based on actual measurement. That is, an estimated value of total power consumption.

The estimated value is the sum of the power consumption of each of the home appliances 200A to 200F, and the specific value is 345 + 114.3 + 0 + 126 + 900 + 1170 = 2655.3 (W)
It is. The estimated value of the total power consumption after the operation mode of the washing / drying machine 200F shifts to 6e exceeds the allowable power consumption of 1900W. The excess is 2655.3-1900 = 755.3 (W)
It is. CPU121 changes the operation mode which each household appliances 200A-200F can take, and extracts the combination from which total power consumption becomes below permissible power consumption.

  Several extraction procedures are possible. One of them is as follows. The total power consumption is calculated using the data shown in FIG. 5 assuming that the operation mode with the lower power consumption is set or the operation is stopped in the order of the IDs assigned to the home appliances. Skip household appliances that have already stopped. If the calculated total power consumption is less than or equal to the allowable power consumption, the combination is extracted. It is assumed that if the operation mode of one household electrical appliance is changed and the power consumption does not become less than the allowable power consumption, the operation mode of the household electrical appliance with the next lowest ID is changed or stopped. If the power consumption still does not fall below the allowable power consumption, the same processing is performed for the next home appliance. In this way, combinations where the total power consumption is less than or equal to the allowable power consumption are extracted.

  If the calculated total power consumption is much lower than the allowable power consumption, then change the operation mode of the device that has a small power saving effect by changing the operation mode in stages to gradually restore the original operation mode to a range where the total power consumption is below the allowable power consumption. Find the operating mode in. In this way, it is possible to achieve reasonable power saving by bringing the total power consumption close to the allowable power consumption.

  The description will be given again along the example of FIG. The CPU 121 changes the air conditioner 200A having the smallest ID to an operation mode with low power consumption by one step. It is assumed that the current operation mode 1v is changed so as to increase the set temperature since the air volume cannot be lowered any more. Since the power consumption of the air conditioner 200A is 345W, even if it is changed to stop (operation mode 1e) as the maximum power reduction, the power consumption is only reduced by 320W from 345W to 25W ("ID1 operation mode in FIG. 6" See “Change” column). The total power consumption cannot be reduced below the allowable power consumption with only the air conditioner 200A. Therefore, in addition to the stop of the air conditioner 200A, power reduction is considered for the refrigerator 200B having the next ID. Assume that the refrigerator temperature and freezer temperature settings are changed from the current “medium / medium” (operation mode 2e) to “off / off” (operation mode 2a). The power consumption changes from 114.3 W to 15 W and is reduced by 99.3 W, but the total power consumption still does not fall below the allowable power consumption (see “ID2 operation mode change” column in FIG. 6). Next, since the electric carpet 200C with the younger ID is stopped (operation mode 3a), the toilet seat temperature and the hot water temperature are changed from the current “low / low” (operation mode 4f) for the hot water washing toilet seat 200D with the younger ID. Assume that the mode is changed to “OFF / OFF” (operation mode 4a). The power consumption changes from 126 W to 24 W and is reduced by 102 W, but the total power consumption does not fall below the allowable power consumption (see the “ID4 operation mode change” column in FIG. 6).

Therefore, it is assumed that the dishwasher / dryer 200E having a lower ID is changed from the current “drying / normal” (operation mode 5g) to “drying / eco” (operation mode 5f). The power consumption is changed from 990 W to 450 W and reduced by 540 W (see “ID5 operation mode change” column in FIG. 6). Here, the total power consumption of each of the home appliances 200A to 200F is
25 + 5 + 0 + 24 + 450 + 1170 = 1673 (W)
Therefore, the total power consumption is less than the allowable power consumption. Therefore, the CPU 121 may extract this as one combination.

However, the total power consumption is well below the allowable power consumption of 1900W, and there is a margin of 226W. Therefore, when it is confirmed that the operation mode cannot be returned to the original operation mode in the reverse order of the IDs, when the warm water washing toilet seat 200D and the refrigerator 200B are returned to the original state, the total power consumption of the home appliances 200A to 200F is:
25 + 114.3 + 0 + 126 + 450 + 1170 = 1885.3 (W)
Therefore, the total power consumption is less than the allowable power consumption. Thus, CPU121 may extract the operation mode as one combination, after readjusting about household appliances with a small change in power consumption even if it changes an operation mode.

The above is a combination extracted assuming that the operation mode is changed in order from the air conditioner with ID = 1, but other combinations can be searched by shifting in order of ID = 2, 3,.
FIG. 7 is a second explanatory diagram illustrating an example of a procedure for determining the operation mode of each home appliance in the peak cut control. FIG. 7 shows a case where combinations are extracted on the assumption that the operation mode is changed in order from the refrigerator 200B with ID = 2. The CPU 121 first changes the refrigerator 200B to “OFF / OFF” (operation mode 2a) (see the “ID2 operation mode change” column in FIG. 7), and further sets the hot water washing toilet seat 200D to “OFF / OFF” (operation mode 4a). (Refer to the “ID4 operation mode change” column in FIG. 7). Even if it does in this way, the sum total of the power consumption of each household appliances 200A-200F is,
345 + 15 + 0 + 24 + 900 + 1170 = 2454 (W)
The total power consumption exceeds the allowable power consumption. Therefore, it is assumed that the dishwasher 200E is changed to “drying / eco” (operation mode 5f) (see the column “ID5 operation mode changed to 5f” in FIG. 7). In this case, the total power consumption of each of the home appliances 200A to 200F is
345 + 15 + 0 + 24 + 450 + 1170 = 2004 (W)
The total power consumption still exceeds the allowable power consumption. Furthermore, when the dishwasher 200E is changed to “OFF” (operation mode 5a) (see “ID5 operation mode changed to 5a” in FIG. 7), the total power consumption is
345 + 15 + 0 + 24 + 5 + 1170 = 1559 (W)
Therefore, the total power consumption is less than the allowable power consumption. Although CPU121 may extract this as one combination, you may readjust about household appliances with a small change of power consumption. When ID4 and ID2 are readjusted, the total power consumption of each home appliance 200A-200F is
345 + 114.3 + 0 + 126 + 5 + 1170 = 1760.3 (W)
(Refer to “ID2 readjustment” in FIG. 7).

Further, consider the case where the washing / drying machine 200F with ID = 6 is at the top.
FIG. 8 is a third explanatory diagram illustrating an example of a procedure for determining an operation mode of each home appliance in peak cut control. When the current “drying / normal” (operation mode 6f) is changed to “drying / air blowing only” (operation mode 6e), the total power consumption of the home appliances 200A to 200F is:
345 + 114.3 + 0 + 126 + 900 + 300 = 1785.3 (W)
As a result, the total power consumption becomes less than the allowable power consumption (see the “ID6 operation mode change” column in FIG. 8). The CPU 121 extracts this as one combination.
As described above, the combinations of the three operation modes shown in FIGS.

  FIG. 9 is an explanatory diagram showing combinations of operation modes extracted by the procedure shown in FIGS. In FIG. 9, a column surrounded by a thick frame line indicates a home appliance that has been changed to an operation mode with low power consumption or stopped for peak cut control in that combination. In “combination 1”, the air conditioner 200A is stopped by peak cut control, and the dishwasher 200E is changed to an operation mode with lower power consumption. In “Combination 2”, the dishwasher 200E is stopped. In “Combination 3”, the washing / drying machine 200F is changed to the operation mode of lower power consumption.

<Peak Cut Control-Other Mode for Determining Operation Mode>
Although an example of the procedure for determining the operation mode of each home appliance for peak cut control has been described above, combinations can be extracted using different procedures.
For example, the CPU 121 calculates the total power consumption when the operation mode of the washing / drying machine 200F shifts to 6e, obtains the ratio to the allowable power consumption, and divides the current power consumption of each home appliance 200 by the ratio. Calculate target power consumption. Then, with reference to the power consumption data storage unit 151, an operation mode lower than the target power consumption is determined for each home appliance 200. However, in this state, the functions of each home appliance 200 are deteriorated or damaged. Therefore, the CPU 121 returns one home appliance to the original operation mode, and when the total power consumption exceeds the allowable power consumption, the CPU 121 changes the operation mode of the other home appliances to a lower power consumption operation mode. Keep power consumption below allowable power consumption. This is extracted as one combination, and each home appliance to be operated is returned to the original operation mode, and a plurality of combinations in which other home appliances are set to the low power consumption operation mode are extracted.
This method is effective when the power consumption of each home appliance can be finely set by changing the operation mode.

<Flowchart>
FIG. 10 is a flowchart showing the processing order of peak cut control executed by the cooperative operation control unit 149 according to the present invention. The process will be described with reference to FIG.
The CPU 121 as the cooperative operation control unit 149 monitors the reception of operation information notifying that any home appliance 200 changes the operation mode (step S11). When receiving the operation information, the CPU 121 refers to the power consumption data storage unit 151 to obtain the power consumption of each home appliance 200 after the migration (step S13), and obtains the total power consumption at that time (step S15). Then, it is determined whether or not the total power consumption after the transition exceeds the allowable power consumption (step S17). If the allowable power consumption is not exceeded (No in step S17), the routine returns to step S11 without particular intervention in the operation mode after the transition, and continues to monitor the operation information.
When the total power consumption after the transition exceeds the allowable power consumption in Step S17 (Yes in Step S17), the CPU 121 refers to the power consumption data storage unit 151 and obtains the total power consumption in Step S15. Also, each home electric appliance is changed to an operation mode with lower power consumption or stopped, and a combination of operation modes estimated to have a total power consumption equal to or lower than an allowable power consumption is extracted (step S19).
Furthermore, the CPU 121 determines whether there is only one or a plurality of combinations of extracted operation modes (step S21). When there is only one way (No in step S21), each home appliance is operated in the extracted operation mode (step S23). When a plurality of combinations are extracted (Yes in step S21), the order of the combinations is determined, and each home electric appliance is operated with the first combination (step S25).
Thereafter, the CPU 121 monitors whether or not operation information notifying the change of the operation mode has been received (step S27). If it is received (Yes in step S27), the routine proceeds to step S13, where the total power consumption is calculated for the operation mode after the transition to check whether the allowable power consumption is exceeded.
On the other hand, while the operation information is not received (No in step S27), the routine proceeds to step S29 and checks whether a predetermined time has elapsed. Here, the predetermined time is a period predetermined as a time interval for switching the operation mode. Until the initial time elapses (No in step S29), the routine follows the loop returning to step S27 and continues to monitor the operation information. When the predetermined time has elapsed (Yes in step S29), each home electric appliance is operated in a combination of operation modes determined as the next order (step S31). When the end of the order is reached, the operation returns to the first combination and the operation mode is switched cyclically.
The above is the flow of the peak cut control process of the cooperative operation control unit 149.
<Peak cut control-Operation mode switching control 1>
FIG. 11 is a graph showing a state in which the cooperative operation control unit 149 according to the present invention performs control so as to change the combination of the operation states of the electric devices and to sequentially switch over time. The vertical axis is power consumption, and the horizontal axis is time. The graph shows how the power consumption and the total power consumption of each of the home appliances 200A to 200F change with time. In FIG. 11, a period P1 in the horizontal axis direction shows a state before the start of peak cut control. The period P2 indicates a state where the operation mode of the washing / drying machine is shifted to 6f and the other home appliances maintain the operation mode of the period P1. The period P2 is a virtual period, and the chain line indicates this. Subsequent C1, C2, and C3 indicate that each home appliance 200 operates in the operation mode corresponding to “combination 1”, “combination 2”, and “combination 3” shown in FIG. C1 represents a period of operation in “combination 1” of FIG. 9, C2 represents a period of operation in “combination 2” of FIG. 9, and C3 represents a period of operation in “combination 3” of FIG. Represents.

As described above, in FIGS. 6 to 11, when the operation mode of the washing / drying machine 200 </ b> F, which is one household electrical appliance, is about to shift from dehydration to drying, it is predicted that the total power consumption will exceed the allowable power consumption and the peak cut An example of starting control was described. At this time, as the cooperative operation control unit 149, the CPU 121 extracts a combination of operation modes in which the total power consumption is less than or equal to the allowable power consumption and does not impair the functions of each home appliance 200 as much as possible. Controls to sequentially switch the combinations.
The time interval at which the cooperative operation control unit 149 switches the combination of operation modes may be determined in advance by the designer of the power management system, and is set and set by the contractor who installs the system or the user who uses the system. You may make it changeable. This time interval is not particularly limited, but if the interval is too short, each home electric appliance cannot follow, and if it is too long, there is no significance of switching over time. Taking an air conditioner as an example, in general, when the air conditioner is stopped, the indoor temperature changes in about several minutes. Therefore, the switching interval is preferably about 2 to 5 minutes. For example, if switching is performed at intervals of 5 seconds, the interval is too short and the response of the air conditioner cannot follow. On the other hand, for example, if switching is performed at intervals of 50 minutes, the user feels uncomfortable because the interval is too long.

<Peak cut control-Operation mode switching control 2>
Some home appliances operate in a short time to perform a predetermined process while others operate constantly. Those that operate in the short term include those in which different operation modes are predetermined as a series of operations and the operation modes are sequentially switched. For convenience, the former is called a steady operation type, and the latter is called a temporary operation type. Further, a temporary operation type that sequentially switches a series of operation modes is called a sequential operation type. Specific examples of the steady operation type are an air conditioner 200A, a refrigerator 200B, an electric carpet 200C, and a warm water washing toilet seat 200D. Specific examples of the temporary operation type are a dishwasher 200E and a laundry dryer 200F. The dishwasher / dryer 200E and the washer / dryer 200F are also sequentially operated.

  The same home appliance may have both sides. For example, when the air conditioner 200A starts the cooling operation, if the difference between the room temperature and the set temperature is large, the full power operation is initially performed with the maximum air volume, but the air volume is gradually decreased as the temperature difference becomes smaller. Regarding full power operation in such a situation, the air conditioner 200A can be said to be a temporary operation type. After the room temperature approaches the set temperature, the cooling operation is continued almost constantly. In the case of air conditioners, the majority can be said to be of steady operation type. When these steady operation type and temporary operation type are included in the power management system, a simpler peak cut control method can be considered. The attribute of which home appliance or operation mode is a steady operation type and which is a temporary operation type is determined by the manufacturer of each home appliance or the manufacturer of the power management apparatus of the present invention and / or the operation mode. The cooperative operation control unit 149 controls each home electric appliance in each aspect according to a predetermined classification.

  The first method is as follows. When the temporary operation type shifts to the next operation mode, the cooperative operation control unit 149 predicts that the total power consumption exceeds the allowable power consumption, but if the period exceeding the allowable power consumption is temporary, any one of the periods Control is performed so that the steady operation type is changed to an operation mode of low power consumption.

  This would be a relatively straightforward method. For example, the above-described example of the air conditioner 200A as a temporary operation type is taken up again. It is assumed that the air conditioner 200A receives an instruction to start the cooling operation from the user. The set temperature is 24 ° C. as in the previous example, but the difference between the room temperature and the set temperature is smaller than in the previous example, and the operation is started with the air volume “weak”. In this case, the air flow is gradually decreased as the temperature difference becomes smaller. In this case, it is assumed that the refrigerator 200B, the warm water washing toilet seat 200D, and the dishwasher 200E are operating, and that the total power consumption exceeds the allowable power consumption by 90 W when the cooling operation of the air conditioner 200A is started.

In this case, if the operation of the air conditioner 200A is reserved, the user feels uncomfortable because the room temperature does not drop. According to this aspect, the CPU 121 as the cooperative operation control unit 149 changes the steady operation type to an operation mode with low power consumption. In this case, the refrigerator 200B and the warm water washing toilet seat 200D are operating as stationary devices. For example, the cooling operation can be started by stopping the refrigerator 200B whose current operation mode is 2e (operation mode 2a). Alternatively, the cooling operation can be started by stopping the hot water washing toilet seat 200D whose current operation mode is 4f (operation mode 4a).
Preferably, the CPU 121 performs control for sequentially switching these two combinations as shown in FIG.

  In the second method, when the sequential operation type shifts to the next operation mode, the total power consumption is predicted to exceed the allowable power consumption, and when the power consumption of other sequential operation types is expected to decrease over time, It waits for the transition. Hereinafter, a specific example will be described.

  FIG. 12 is a graph showing changes in power consumption when the dishwasher / dryer 200E and the laundry / dryer 200F as the sequential operation type operate by switching a series of operation modes instructed by a user within a predetermined period. It is. FIG. 12A shows the transition of the power consumption of the dishwasher 200E, and FIG. 12B shows the transition of the power consumption of the laundry dryer 200F.

  As shown in FIG. 12A, when there is no peak cut control, the dishwasher / dryer 200E that receives an instruction from the user operates according to the instructed cleaning course. That is, cleaning water is heated for the first 5 minutes (operation mode is 5b), followed by washing for 12 minutes (operation mode is 5c), rinse for 4 minutes and 30 seconds (operation mode is 5d) twice, and heating for 14 minutes. Rinsing (operation mode is 5e) once, rinsing for 4 minutes and 30 seconds (operation mode is 5d), and drying for 25 minutes (operation mode is 5 g) are sequentially executed.

  As shown in FIG. 12B, when there is no peak cut control, the washing / drying machine 200F that has received an instruction from the user operates in accordance with the instructed washing course. That is, wash for the first 12 minutes (operation mode is 6b), then rinse for 15 minutes (operation mode is 6c), dehydrate for 23 minutes (operation mode is 6d), and dry for 95 minutes (operation mode is 6f). Run sequentially.

  FIG. 13 is a graph showing an example of the operation at the time of peak cut control of the dishwasher / dryer 200E and the laundry / dryer 200F receiving the instruction. The vertical axis represents power consumption, and the horizontal axis represents the passage of time. As shown in FIG. 13, when the set temperature of the air conditioner 200 </ b> A is 24 ° C. and the difference between the room temperature and the set temperature is large, the air volume is gradually decreased as the temperature difference becomes smaller when operating at the air volume “strong” at the time origin. Drive down. Assume that the dishwasher / dryer 200E receives the instruction to start the washing course at the time origin, and the washing / drying machine 200F receives the instruction to start the washing course immediately after that.

  When the CPU 121 as the cooperative operation control unit 149 obtains the operation information from the dishwasher / dryer 200E and the washer / dryer 200F, the CPU 121 calculates an estimated value of the total power consumption when operating in accordance with the operation modes. When the dishwasher / dryer 200E to be operated first executes washing water heating (operation mode 5b), the total power consumption exceeds the allowable power consumption. At this time, the air conditioner 200 </ b> A is sequentially operated and can be predicted to gradually reduce the air volume as the temperature difference decreases. Accordingly, the CPU 121 reserves the start of washing water heating (the operation mode is 5b) of the dishwasher 200E.

  When the airflow of the air conditioner 200A changes from “strong” to “weak” after 15 minutes, the CPU 121 assumes that the dishwasher 200E starts washing water heating (operation mode is 5b) in response to the operation information from the air conditioner 200A. The total power consumption is calculated again. As a result, since the total power consumption becomes equal to or less than the allowable power consumption, the dishwasher 200E is instructed to start the washing water heating (operation mode is 5b). As described above, the dishwasher 200E starts washing after waiting for 15 minutes. However, the washing / drying of the washing / drying machine 200F (operation mode is 6b) continues to be reserved. This is to prevent the total power consumption from exceeding the allowable power consumption.

  In response to the instruction, the dishwasher 200E executes the operation of the washing course shown in FIG. After 20 minutes from the time origin, the operation mode of the dishwasher 200E changes from washing water heating (operation mode is 5b) to washing (operation mode is 5c). The CPU 121 that has received the operation information recalculates an estimated value of the total power consumption, and instructs the washing / drying machine 200F to start washing (operation mode is 6b). As described above, the washing / drying machine 200F starts washing after waiting for 20 minutes.

  In response to the instruction, the washing / drying machine 200F starts the operation of the selected course shown in FIG. 12B, and passes through washing (operation mode is 6b), rinsing (operation mode is 6c), and dehydration (operation mode is 6d). Then, the drying (operation mode is 6f) is started after 75 has elapsed from the time origin. Receiving this operation information from the washing / drying machine 200F, the CPU 121 calculates an estimated value of the total power consumption, determines that the total power consumption exceeds the allowable power consumption when shifting to drying, and reserves the start of drying.

After 100 minutes from the time origin, washing of the dishwasher 200E is completed. Receiving the operation information, the CPU 121 calculates an estimated value of the total power consumption and instructs the laundry dryer 200F that has been reserved to start drying. As described above, the washing / drying machine 200F starts drying after waiting for 25 minutes after the completion of dehydration.
The above is a specific example of the technique in which the cooperative operation control unit 149 performs the peak cut control while waiting for the transition of the operation mode for the sequential operation type.

In the above description, when the operation mode of the home appliance changes, the CPU 121 calculates the total power consumption after the transition using the data stored in the power consumption data storage unit before the home appliance transitions to the operation mode. Predict and perform peak cut control when the allowable power consumption is exceeded.
As a different mode, the home appliance is operated for a while in the operation mode after the transition, the total power consumption is measured by the CT sensor 305, and the peak cut control can be performed when the allowable power consumption is exceeded. The total power consumption, which is simply the sum of the power consumption of individual home appliances due to the power factor, has an error from the actual measurement value. The advantage of this mode is that the total power consumption is measured and reliably kept below the allowable power consumption. It is in. This method can be applied when it is allowed to exceed the allowable power consumption for a short period.

  In any method, when extracting a combination of operation modes of each household electrical appliance, the data stored in the power consumption data storage unit 151 is used to perform processing in a short time. Estimate the total power consumption after entering or stopping the operation mode. Then, the total power consumption is measured using the CT sensor 305 when actually operating in the extracted operation mode. When the measured total power consumption exceeds the allowable power consumption, the operation mode of each home appliance 200 is further changed so as to further suppress the power consumption by the excess amount.

  In addition to the embodiments described above, there can be various modifications of the present invention. These modifications should not be construed as not belonging to the scope of the present invention. The present invention should include the meaning equivalent to the scope of the claims and all modifications within the scope.

11: Power management system 120: HEMS controller 121: CPU
122: Memory 123: Display 124: Touch panel 125: Operation button 126: Communication interface 127: Output interface 128: Input interface 129: Hard disk 131: Speaker 132: Clock 141: Communication unit 143: Total power consumption calculation unit 145: Allowable power consumption Holding unit 147: comparison unit 149: cooperative operation control unit 151: power consumption data storage unit 153: power measurement control unit 200: home appliance 200A: air conditioner 200B: refrigerator 200C: electric carpet 200D: warm water washing toilet seat 200E: dishwasher / dryer 200F : Washing / drying machines 250, 250A, 250B, 250C, 250D, 250E, 250F: Power plug 300: Distribution board 305: CT sensors 400, 400A, 400B, 400C, 400D, 400E, 00F: Power meter 401: Network 402: Power line 4001: Power socket 4002: Power plug 4003: shunt resistor 4004 and 4005: Main wiring 4007: Power unit 4010: power detecting unit 4011: Voltage Input ADC
4012: Current input ADC
4013: Multiplier 4014: Digital / frequency converter 4020: Communication module 4021: CPU
4022: ROM
4023: RAM
4024: GPIO
4025: Wireless RF unit 4030: Antenna 4041: LED
4042: Setting button

Claims (6)

A communication unit that communicates with a plurality of electric devices, receives operation information indicating an operation state of each electric device and power information relating to power consumption of each electric device, and transmits an instruction to change the operation state of the electric device;
A power consumption data storage unit for preliminarily storing power consumption in association with operating states that each electrical device can take;
A total power consumption calculation unit that calculates total power consumption as the total power consumption of each electrical device;
A comparison unit for comparing whether the total power consumption exceeds a predetermined allowable power consumption;
A cooperative operation control unit that controls to issue an instruction to change the operation state of each electrical device when the total power consumption exceeds the allowable power consumption,
The total power consumption calculation unit obtains the total power consumption after transition based on the transitioned operation state in response to the communication unit receiving operation information notifying that the operation state of any electrical device changes. ,
When the total power consumption after the transition exceeds the allowable power consumption, the cooperative operation control unit determines whether the total power consumption after the transition at that time when each electrical device is transitioned or stopped to an operation state with lower power consumption. When a combination of operation states of each electrical device that can be accommodated in the allowable power consumption is extracted and a plurality of combinations can be extracted, an instruction to change the operation state of each electrical device is repeatedly issued over time and the plurality of combinations Power management device that controls to sequentially switch combinations of the two.   The total power consumption calculation unit refers to the power consumption data storage unit in response to operation information indicating that the operation state of any of the electrical devices changes, and based on the power consumption associated with the operation state after the transition The power management apparatus according to claim 1, wherein the total power consumption after migration is acquired. It further comprises a total power consumption measurement unit that measures the total power consumption of the system that manages the power in the house,
The total power consumption calculation unit refers to the total power consumption measured by the total power consumption measurement unit after the transition in response to the operation information indicating that the operation state of any electrical device is changed, and determines the total power consumption after the transition. The power management apparatus according to claim 1 to be acquired. Each electric device and / or each operation state is pre-assigned with either a steady operation type that operates normally or a temporary operation type that operates temporarily,
When the total power consumption after the transition exceeds the allowable power consumption due to a change in the operation state of the temporary operation type electric device, the cooperative operation control unit operates at a lower power consumption only for each of the steady operation type electric devices. When a transition is made to a state, a combination of operating states of each electrical device is extracted so that the total power consumption after the transition falls within the allowable power consumption, and when multiple combinations can be extracted, the operation of each electrical device The power management apparatus according to claim 1, wherein the power management apparatus controls the state to change. Among the temporary operation type electrical devices, the sequential operation type attribute is further given to the electrical devices that operate by sequentially switching the series of operation states and / or the series of operation states.
In the case where the total power consumption after the transition exceeds the allowable power consumption due to the change in the operation state of the sequential operation type electrical device, the cooperative operation control unit is configured for any one of the sequential operation type electrical devices. When waiting for the transition of the operating state, extract one operating state combination of each electrical device so that the total power consumption after the transition is within the allowable power consumption, and based on the extracted combination, The power management apparatus according to claim 4, wherein the power management apparatus controls the operation state of the electric device so as to change over time.   A power management system comprising the power management apparatus according to claim 1.