JP2023017490A - Power apparatus and private power management system - Google Patents

Abstract

To provide a power apparatus which is operated by receiving supply of power from a power system or a private power management system during interconnection and by receiving supply of power from a power supply device for supplying generated or stored power during independence, and the private power management system.SOLUTION: An electric apparatus comprises: a communication circuit for acquiring from an external power management device a value representing a system interconnection state of whether a private power management system including a power generation device or a power storage device is interconnected with a power system or independent of the power system; an operation circuit which performs a running operation by receiving supply of power from the power supply device in a case where the system is independent of the power system and by receiving supply of power from the power system or the power supply device in a case where the system is interconnected with the power system; a switch circuit for turning on and turning off the power supply to the operation circuit; and a control unit for controlling the operation circuit. Upon receiving the switch circuit ON, the control unit performs different control in accordance with whether the value representing the system interconnection state acquired by the communication circuit is a value representing the interconnection or a value representing the independence.SELECTED DRAWING: Figure 5

Description

The present invention provides a power device and the power supply device that receive power from a power grid or a private power management system during interconnection, and receive power from a power supply device that supplies generated or stored power during isolation, and the power supply device. It relates to a private power management system including.

2. Description of the Related Art A self-power management system that charges a storage battery with power generated using natural energy such as a photovoltaic power generation device and power supplied from a power system is known.
A conventional private power management system has a configuration in which power generated using natural energy or power stored in a storage battery is supplied only to a part of electrical devices in an independent grid-connected state. However, as the performance of storage batteries improves and spreads, and as people become more aware of how to respond to disasters, they will be able to use power generation or storage batteries within their own power management system in the event that power is not supplied from the power grid. A configuration is being adopted in which the stored electric power can be supplied not only to some electrical devices but also to all electrical devices in the home.
In particular, in a private power management system configured to supply power to all electrical devices in the home, all electrical devices will be can be supplied with power generated by the generator or power from a storage battery. For this reason, in the event of a power outage, the conventional private power management system could only use a part of the electrical devices in the home, whereas the private power management system can supply power to all the electrical devices in the home. The system can be used with all electrical devices in the home, providing great convenience during power outages. On the other hand, it is difficult for users to notice a power outage because they can use electrical equipment even during a power outage in the same way as when power is being supplied from the power grid.
For example, the following techniques are known as methods of notifying users of power outages. When the energy management system detects a power outage, it notifies the communication terminal that displays the information from the energy management system of the power outage information, and the communication terminal that receives the power outage information displays a power outage icon, character string, or the like indicating that the power outage is in progress. Further, when the energy management device detects a power recovery, it notifies the communication terminal of the power recovery information, and the communication terminal that receives the power recovery information displays a power recovery icon, a character string, or the like indicating that the power has been recovered. (See Patent Document 1, for example).

JP 2014-033578 A

Since the power generated by the private power management system or the amount of power stored in the storage battery is finite, it is desired to suppress wasteful power consumption in the state of independent grid connection. Therefore, it is desirable to avoid a situation in which power is not saved because the user does not notice that the grid-connected state has changed from the grid-connected state to the independent state.
As in Patent Document 1, there is also a method of including power failure information and power recovery information in information provided by an energy management device of an energy management system and displaying the information on a communication terminal. However, this method is troublesome because the user needs to check the display of the communication terminal each time the electric device is used.
The present invention has been made in consideration of the circumstances as described above, and the user can recognize that the grid connection state is independent, that is, during a power failure, and does not notice the power failure. It reduces the risk of using electrical equipment without it and consuming electricity.

This invention
a communication circuit for acquiring from an external power management device a value representing a grid interconnection state of whether a private power management system including a power generation device or a power storage device is interconnected with a power grid or independent of the power grid; When the private power management system is independent of the power system, power is supplied from a power supply device that supplies power generated or stored in the private power management system, and the private power management system is connected to the power system. an operating circuit that receives power from the electric power system or the power supply device to operate when the power system is connected, a switch circuit that turns on and off the power supply to the operating circuit, and a control that controls the operating circuit. and the control unit receives an operation to turn on the switch circuit, and the value representing the system interconnection state acquired by the communication circuit differs depending on whether the value represents interconnection or independence. Provide an electrical device that controls

Also, this invention
a power management device that provides a value representing a grid interconnection state of whether a private power management system including a power generation device or a power storage device is interconnected with a power grid or independent of the power grid; A power supply device that supplies electric power or power stored by a power storage device; and if the private power management system is independent of the power system, the power is supplied from the power supply device, and the private power management system receives the power from the power system. an operating circuit that receives power from the electric power system or the power supply device to operate when connected to the power system, a switch circuit that turns on and off the power supply to the operating circuit, and the operating circuit. an electric device including a control unit, wherein the control unit communicates with the power management device to obtain a value representing the grid connection state when receiving an operation to turn on the switch circuit; Provided is a private power management system that performs different control depending on whether a system state is a value representing interconnection or a value representing independence.

In the electrical equipment according to the present invention, when an operation to turn on the switch circuit is received, different control is performed depending on whether the grid-connected state is interconnected or independent, so the grid-connected state is an independent state. It is possible to reduce the risk of power consumption due to the use of electrical equipment without the user noticing this fact.
The private power management system according to the present invention also has similar effects.

It is a block diagram which shows the structural example of the self-power management system in this embodiment. FIG. 2 is a block diagram showing a configuration example different from FIG. 1 of the private power management system in this embodiment; FIG. 3 is a block diagram showing a configuration example different from FIGS. 1 and 2 of the private power management system in this embodiment; FIG. 2 is a block diagram showing a configuration example of the electric device shown in FIG. 1; FIG. 5 is a flowchart showing an example of processing executed by a control unit when power is turned on in Embodiment 1. FIG. FIG. 10 is an explanatory diagram showing an operation different from that during interconnection when the power of the television is turned on while the system interconnection state is independent in the first embodiment; 10 is a flowchart showing an example of processing executed by a control unit when power is turned on in Embodiment 2. FIG. FIG. 10 is an explanatory diagram showing an operation different from that during interconnection when the power of the television is turned on while the system interconnection state is independent in the second embodiment; 10 is a flowchart showing an example of processing executed by a control unit when power is turned on in Embodiment 3. FIG.

The present invention will be described in further detail below with reference to the drawings. It should be noted that the following description is illustrative in all respects and should not be construed as limiting the present invention.
(Embodiment 1)
<<Configuration example of private power management system>>
First, the configuration of a house power system according to this embodiment will be described as an example of a private power management system according to the present invention.

FIG. 1 is a block diagram showing a configuration example of a private power management system in this embodiment. Although FIG. 1 shows an example in which the private power management system 10 is installed in a detached house, the installation location of the private power management system is not limited to this. For example, it may be a building where people live, such as an apartment complex, a store, a factory, or a warehouse.
In FIG. 1 , along with the private power management system 10, a system power network 21 and an electric device 19 that is a power load are also illustrated.

A private power management system 10 shown in FIG. Furthermore, the distribution board 14 is provided.
The power monitor 16 functions integrally with the power conditioner 12, and provides information such as power generation status and grid connection status, in addition to controlling power generation and power storage. The grid connection status information is information indicating whether the private power management system 10 is linked to the grid power network 21 or independent, and the power conditioner 12 acquires it and notifies it to the power monitor 16. do.

The solar cell module 11 is a module that converts light energy of sunlight into electric energy.
The power conditioner 12 converts the electric power generated by the solar cell module 11 and the electric power of the system power network 21 so that the storage battery 13 can be charged, and also converts the electric power generated by the solar cell module 11 and the electric power stored in the storage battery 13 . It is a device that converts electric power so that it can be used by the electrical equipment 19 . In other words, the power conditioner 12 is a power supply device that supplies power to electrical equipment. The power conditioner 12 includes a DC/DC converter connected to the solar cell module 11, a bidirectional DC/DC converter connected to the storage battery 13, and a bidirectional inverter connected to the system power grid 21 via the distribution board 14. Prepare. Then, the DC power output from the solar cell module 11 and the storage battery 13 is converted into AC power, and the AC power from the system power network 21 is converted into DC power to charge the storage battery. The power conditioner 12 also includes a communication circuit for communicating with the power monitor. One example is a serial communication circuit conforming to the RS485 communication standard.

The storage battery 13 is a power storage device that stores electrical energy, and stores the electrical energy generated by the solar cell module 11 or the electrical energy supplied from the power grid 21 .
The distribution board 14 distributes electric power drawn from the grid power network 21 and electric power supplied from the solar cell module 11 and the storage battery 13 to the electric devices 19 in the home.

The power monitor 16 acquires power information of the private power management system 10 and controls the operation of the power conditioner 12 according to the power information. The power information includes, for example, information indicating the state of purchasing or selling commercial power, information indicating the power generated by the solar cell module 11, and information indicating the charging power or discharging power of the storage battery 13, and the like.
By connecting a sensor to the power line that connects the distribution board 14 and the grid power network 21, the state of commercial power purchase or sale and the amount of power purchase or sale can be specified from the output value of the sensor. Information indicating the power generated by the solar cell module 11 and the charge/discharge power of the storage battery 13 can be obtained via the power conditioner 12 .
Furthermore, since the storage battery 13 is connected to the power conditioner 12 , the power monitor 16 can perform control such as switching between charge and discharge of the storage battery 13 via the power conditioner 12 .

The power monitor 16 in this embodiment is mainly composed of a CPU (Central Processing Unit) or MPU (Micro Processing Unit) and a memory from the viewpoint of hardware configuration. The CPU or MPU (hereinafter collectively referred to as CPU) executes the processing program stored in the memory to control the functions related to charge/discharge control of the storage battery 13 . Further, power monitor 16 includes a first communication circuit for communicating with inverter 12 and a second communication circuit for communicating with electrical equipment 19 . The first communication circuit is, for example, a serial communication circuit conforming to the RS485 communication standard, and the second communication circuit is a LAN (local area network) for communicating with electrical equipment 19 connected to a home network. ) may be a communication circuit conforming to the standard. Power monitor 16 may be configured to communicate with a mobile communication terminal (not shown) over a second communication circuit.

The private power management system 10 is connected with electric devices 19 such as air conditioners (so-called air conditioners, air purifiers, etc.), cooking appliances, video equipment, and other devices that consume power. can supply. These devices are also connected to a home network (local area network). The power monitor 16 provides each electrical device 19 with grid connection status information via the home network.
The home network may be, for example, a network conforming to the ECHONET (registered trademark) standard or the ECHONET Lite standard, but is not limited to this. Other communication standards and manufacturer-specific communication standards are also possible.
Note that, for example, by configuring the power monitor 16 to detect the voltage outside the home of the distribution board 14, the private power management system 10 can detect whether it is interconnected (connected state) with the grid power network 21 or independent. It can be judged whether it is medium (independent state). With such a configuration, it is also possible for the power monitor 16 to provide each electrical device 19 with grid connection status information. Specifically, each electrical device 19 communicates with the power monitor 16 in accordance with the communication standard to obtain a value representing the grid connection state.

2 and 3 show an aspect different from the configuration shown in FIG.
FIG. 2 shows a configuration in which a HEMS controller 17 is communicatively connected to each electrical device 19 instead of the power monitor 16 shown in FIG. The power conditioner 12 has a communication circuit for communicating with the HEMS controller 17 . One example is a serial communication circuit conforming to the RS485 communication standard. The configuration shown in FIG. 2 can be said to be a mode in which the HEMS controller 17 includes the function of the power monitor 16 and the power monitor 16 as an independent device does not exist.
In the configuration shown in FIG. 2, a HEMS (Home Energy Management System) is configured by an indoor HEMS controller 17 and an outdoor HEMS server 22 that communicates via the Internet. The HEMS controller 17 transmits to the HEMS server 22, via the Internet, information such as the device configuration, power generation status, grid connection status, etc. regarding power generation and power storage of the private power management system. The HEMS server 22 provides the mobile communication terminal 18 with the information transmitted from the HEMS controller 17, such as the device configuration, power generation status, grid connection status, etc., related to power generation and power storage. That is, by accessing the HEMS server 22 using the mobile communication terminal 18, the user can confirm information such as the equipment configuration, power generation status, grid connection status, etc. related to power generation and power storage of the private power management system even outside the home. In addition, the HEMS controller 17 acquires information necessary for the operation of the private power management system 10 from the HEMS server 22 or external devices connected via the Internet. It also transmits information on the private power management system to the HEMS server 22 .
In the configuration example shown in FIG. 2, the HEMS controller 17 corresponds to a power management device that provides grid connection status information to electrical equipment.

Furthermore, the HEMS controller 17 may display the operating state of each electrical device 19 on the user's mobile communication terminal 18, and may receive a user's instruction regarding the operation control of each electrical device 19 via the mobile communication terminal 18. . A data transmitter that transmits detected values of electric power or current supplied to each electrical device 19 or sensing information such as room temperature may be connected to the HEMS controller 17 . The HEMS controller 17 can cause the mobile communication terminal 18 to display the power consumption of electrical equipment in the home.
The HEMS controller 17 in this embodiment is mainly composed of a CPU (Central Processing Unit) or MPU (Micro Processing Unit) and memory from the viewpoint of hardware configuration. The CPU or MPU (hereinafter collectively referred to as CPU) executes the processing program stored in the memory to control the functions related to charge/discharge control of the storage battery 13 . Furthermore, the HEMS controller 17 includes a third communication circuit for communicating with the power conditioner 12 and a fourth communication circuit for communicating with the electrical equipment 19 . The third communication circuit is, for example, a serial communication circuit conforming to the RS485 communication standard, and the fourth communication circuit is a LAN (local area network) for communicating with the electrical equipment 19 connected to the home network. ) may be a communication circuit conforming to the standard.

As described above, in the configuration example shown in FIG. 2 , the HEMS controller 17 includes the functions of the power monitor 16 . On the other hand, the configuration example shown in FIG. 3 is a mode in which the HEMS controller 17 and the power monitor 16 exist as devices connected to the home network. The power monitor 16 shown in FIG. 3 is connected to the power conditioner 12 via the first communication circuit in the same manner as the power monitor 16 shown in FIG. 1, and functions in the same manner as the power monitor 16 shown in FIG. The HEMS controller 17 shown in FIG. 3 is obtained by removing the function corresponding to the power monitor 16 from the HEMS controller 17 shown in FIG. 2, and provides the function related to HEMS. The HEMS controller 17 shown in FIG. 3 is connected to the electric device 19 via the fourth communication circuit, similarly to the HEMS controller 17 shown in FIG. 2, and functions similarly to the HEMS controller 17 shown in FIG.

FIG. 4 is a block diagram showing a configuration example of the electrical equipment 19 shown in FIG.
The electric device 19 shown in FIG. 4 includes a control section 41 , a communication circuit 43 , an operation circuit 45 , a switch circuit 47 , a power supply circuit 49 and a remote controller 51 .
The control section 41 controls the operation of the electrical equipment 19 . The hardware consists of a control circuit centering on a microprocessor (MPU). The functions of the control unit 41 are realized by the MPU executing the control program.

The communication circuit 43 is a circuit that communicates with an external device. As shown in FIG. 1, each electrical device 19 communicates with the power monitor 16 and the HEMS controller 17 via the home network. Then, at least when the power is turned on, the system interconnection state information is acquired from the power monitor 16 and the HEMS controller 17 . It is preferable to acquire the grid interconnection status at appropriate times even after the power is turned on. The control unit 41 may timely acquire the grid connection state recognized by the power monitor 16 and the HEMS controller 17 . Alternatively, the power monitor 16 or the HEMS controller 17 may timely inform each electric device 19 of the grid interconnection state regardless of whether or not there is a request from each electric device 19 .
2, instead of the power monitor 16 shown in FIG. 4, the communication circuit 43 is connected to the HEMS controller 17 via the home network. Further, in the case of the configuration example shown in FIG. 3, in addition to the power monitor 16 shown in FIG. 4, the communication circuit 43 is connected to the HEMS controller 17 via the home network.

The operation circuit 45 is a circuit that operates by receiving power supply from the grid power network 21 or the private power management system 10 , and is a circuit that implements the functions of the electric device 19 . For example, an operating circuit in a refrigerator corresponds to a circuit such as a compressor for cooling the interior of the refrigerator, a lighting and temperature control circuit for the interior of the refrigerator, and the like. Further, the operating circuit in the television corresponds to an input/output interface circuit for video signals, a processing circuit for video signals, a display device, and the like. It also corresponds to a control circuit or the like for controlling the operation of an air compressor or a heat exchanger of an air conditioner. Further, operational circuitry 45 includes circuitry associated with the user interface of electrical device 19 . It is a circuit related to an audio output circuit, an indicator lamp, a message display device, etc. for notifying the user of the operating state of the electrical equipment 19 by voice or display. The operation circuit 45 operates means that the electrical equipment 19 performs a normal operation (operating operation) in which its function is exhibited and an operation of informing the user that the system interconnection state is in the process of being isolated. Further, the fact that the operation circuit operates means that the electric device 19 operates normally to exhibit its function.

The switch circuit 47 is a circuit that switches whether or not to supply the power supplied from the grid power network 21 or the private power management system 10 to the power supply circuit 49 described later. For example, relays, transistors, SSRs (Solid State Relays), etc. are applied. The switch circuit 47 independently performs the operation of switching the electric device 19 from the power-off state to the power-on state. This is because the control unit 41 does not operate when the power is off. However, when power is being supplied to the control unit 41 , the switch circuit 47 performs the operation of turning off and on the power supply under the control of the control unit 41 .
The power supply circuit 49 is a circuit that receives power supply from the system power network 21 or the private power management system 10 via the switch circuit 47 and supplies power to the control unit 41 , the communication circuit 43 and the operation circuit 45 .
In this embodiment, the remote controller 51 receives a user's operation and transmits an optical signal to the main body of the electrical device 19 . In addition to or instead of the remote controller 51, the electric device 19 may include an operation unit (not shown in FIG. 4), and the operation unit may receive the user's operation.

Returning to the description of FIGS. In this embodiment, the mobile communication terminal 18 has a communication function and an information output function. A user of the private power management system 10 can use the mobile communication terminal 18 to check the power generation status of the private power management system 10, the charging/discharging status of the storage battery, or the remaining capacity.
More specifically, it is preferable that the mobile communication terminal 18 be a smart phone, a tablet terminal, or the like. However, the terminal device is not limited to this, and may be a stationary terminal device such as a personal computer. Mobile communication terminal 18 communicates with power monitor 16 and HEMS controller 17 via a local area network. It also communicates with the HEMS server 22 via the Internet. In the case of a mobile communication terminal, it is assumed that communication is performed wirelessly, but in the case of a stationary terminal device, wired communication may be used.

Although the HEMS server 22 is a single server in FIGS. 2 and 3, it may be composed of a server group in which a plurality of servers cooperate to perform processing. The HEMS server 22 communicates with the HEMS controller 17 via the Internet, and communicates with the private power management system 10, for example, information (power information) related to power such as the amount of power generated, the amount of power consumed, the amount of power sold, the amount of power purchased, and the remaining capacity of a storage battery. , exchanges information (operation information) relating to the operation state of the private power management system 10 and the electrical equipment 19 .

<<Processing of the control unit when the power is turned on>>
Next, processing executed by the control unit 41 of the electric device 19 when the power of the electric device 19 is turned on will be described.
FIG. 5 is a flowchart showing an example of processing executed by the control unit 41 when power is turned on in this embodiment.
As described above, when the remote controller 51 receives a user's power-on operation, the switch circuit 47 supplies power from the private power management system 10 to the power supply circuit 49 in response to the operation, and the power supply circuit 49 is turned on. Power is supplied to the control unit 41 , the communication circuit 43 and the operating circuit 45 . When power is supplied from the power supply circuit 49, the control unit 41 starts processing.

When starting the processing, the control unit 41 performs predetermined initialization processing on its own circuits, the communication circuit 43 and the operation circuit 45, and then communicates with the HEMS controller 17 via the communication circuit 43 to establish system interconnection. State information is acquired (step S11).
If the acquired grid interconnection status information is a value indicating interconnection (No in step S13), the control unit 41 controls the operation circuit 45 to start operation (step S19). In other words, the operation of exhibiting the function of the electric device 19 is started, and the power-on processing is terminated.
On the other hand, if the acquired grid connection state is a value representing independence (Yes in step S13), the control unit 41 does not start the operation at that time, and informs the user that the power is out. A predetermined operation for notification is performed (step S15).

For example, FIG. 6 shows a television as an example of the electrical equipment 19 . The normal operation of the television when the power is turned on is to display images such as broadcasts on the display section 53 . However, in the example shown in FIG. 6, instead of displaying images such as broadcasting on the display unit 53 of the television, the control unit 41 of the television gives, for example, voice notification or blinks a predetermined display lamp of the electric device 19. Such a method is used to notify the user of a power outage. As a different form of the power failure notification, a power failure message (power failure message 55) may be displayed as shown in FIG. The display of the message as shown in FIG. 6 is merely an example, and any method or mode of notification can be used as long as the user can recognize that it is not in a normal state. Appropriate notification means can be employed according to the configuration of the electrical equipment 19 .

Returning to the description of FIG. After notifying that the power is out, the control unit 41 monitors whether or not the operation to turn on the electric device 19 is performed again within a predetermined period (step S17). For example, in the case of the television shown in FIG. 6, if a power failure occurs when the power button of the remote controller 51 is operated while the power is off, the control unit 41 causes the display unit 53 to display a power failure message 55. After the power failure message 55 is displayed, the monitoring of whether or not the power button is operated again is continued until a predetermined period (for example, 3 seconds) elapses (through No in step S17 and No in step S21). loop).
If an operation to turn on the power again is performed within that period (Yes in step S17), the control unit 41 notifies that the power is out and then turns on the power again because it is the user's will. Then, the operation circuit 45 is controlled to start driving operation (step S19). Then, the processing at power-on ends.
On the other hand, if the operation to turn on the power again is not performed within the period (Yes in step S21), the control unit 41 terminates the notification started in step S15, and causes the switch circuit 47 to turn off the power of the electric device 19. to end the process.
The above is the processing executed by the control unit 41 when the power is turned on in this embodiment.

(Embodiment 2)
In Embodiment 1, when the electric device 19 is powered off and the power is turned on and the grid connection state is independent, the operation is performed to notify the power failure without performing the operation.
On the other hand, in this embodiment, when a power-on operation is performed in a power-off state and the system interconnection state is independent, an operation is performed and an operation to notify that a power failure is in progress is performed.
FIG. 7 is a flow chart showing an example of processing executed by the control unit 41 when the power is turned on in this embodiment. In FIG. 7, the same reference numerals are assigned to the same processes as in FIG. 5 according to the first embodiment. The processing of the control unit 41 will be described along FIG. 7, focusing mainly on the points different from FIG.

When the power is turned on and the control unit 41 starts processing, it performs predetermined initialization processing, and then acquires grid interconnection state information (step S11).
If the acquired grid interconnection status information is a value indicating interconnection (No in step S13), the operation is started (step S19) and the power-on processing is terminated.
If the acquired grid connection status information is a value indicating independence (Yes in step S13), the control unit 41 performs a predetermined operation to notify the user that the power is out (step S31). After that, the driving operation is started (step S19), and the processing at the time of power-on is finished.
Note that the operation related to the notification that starts in step S31 may continue until a predetermined period of time elapses, and may be terminated when that period of time elapses, or may be continued while the grid connection state is independent. may

For example, FIG. 8 shows a television as an example of the electrical equipment 19 . The normal operation of the television when the power is turned on is to display images such as broadcasts on the display section 53 . In the example shown in FIG. 8, the control unit 41 of the television causes the display unit 53 of the television to display an image such as a broadcast, and displays a pop-up message (power failure pop-up 57) informing of a power failure. However, the display of the power outage popup 57 as shown in FIG. 8 is merely an example. As different forms of notification of power failure, there are, for example, notification by sound and blinking of a predetermined display lamp of the electrical equipment 19 . In addition, as long as the user can recognize that it is not in a normal state, the notification means and mode are not limited. Appropriate notification means can be employed according to the configuration of the electrical equipment 19 .
The above is the processing executed by the control unit 41 when the power is turned on in this embodiment.

(Embodiment 3)
In Embodiments 1 and 2, when the system interconnection state when the power is turned on is independent, the operation of notifying that a power failure is occurring is performed as an operation different from that during interconnection.
In this embodiment, the control unit 41 performs control to operate in a mode that consumes less power than the operating operation during interconnection as an operation different from that during interconnection.
FIG. 9 is a flowchart showing an example of processing executed by the control unit 41 when power is turned on in this embodiment. In FIG. 9, the same reference numerals are assigned to the same processes as in FIG. 5 according to the first embodiment. The processing of the control unit 41 will be described along FIG. 9, focusing mainly on the points different from FIG.

When the power is turned on and the control unit 41 starts processing, it performs predetermined initialization processing, and then acquires grid interconnection state information (step S11).
If the acquired grid interconnection status information is a value indicating interconnection (No in step S13), the operation is started (step S41) and the power-on processing is terminated.
If the acquired grid interconnection status information is a value indicating independence (Yes in step S13), the control unit 41 starts operation in a mode that consumes less power than the operation during interconnection (step S43). ). Furthermore, a predetermined operation may be performed to notify the user that the power is out (step S45). Then, the processing at power-on ends.

It should be noted that the operation of informing the power failure in step S45 is a preferable mode, but not essential. When the notification is performed, the control unit 41 may continue the notification until a predetermined period elapses and terminate the notification when the period elapses, or continue the notification while the system interconnection state is independent. may
Further, the notification operation shown as a preferred mode in FIG. 9 is similar to the second embodiment in that it is performed at the same time as the driving motion is started, but the notification operation may be performed in a manner similar to that of the first embodiment. That is, when the power-on operation is performed and the system interconnection state is independent, the control unit 41 performs control to perform the notification without performing the operation operation, and the power-on operation is performed again within a predetermined period. In this case, the operating operation may be started in a mode that consumes less power than the operating operation during interconnection.
The above is the processing executed by the control unit 41 when the power is turned on in this embodiment.

As mentioned above,
(i) The electrical equipment according to the present invention receives a value representing the grid connection state of whether a private power management system equipped with a power generation device or a power storage device is interconnected with a power grid or independent of the power grid. When the private power management system is independent of the power system, the power is supplied from the power supply device that supplies the power generated or stored in the private power management system, and the private power management system is connected to the power system, the operation circuit receives power from the power system or the power supply device and operates, the switch circuit turns on and off the power supply to the operation circuit, and the operation circuit is controlled. and a control unit, wherein when an operation to turn on the switch circuit is received, the control unit performs different control depending on whether the value representing the system interconnection state acquired by the communication circuit is a value representing interconnection or a value representing independence. characterized by performing

In the present invention, the private power management system includes at least one of a private power generation device that generates power using natural energy, such as a solar power generation device, and a power storage device. For example, a system (storage device) that does not include a private power generator but has a storage battery as an emergency power supply in preparation for a power failure and charges the storage battery with power from the power grid is also included in the private power management system. It is extremely preferable that the power storage device has a structure capable of supplying electric power to all electrical devices in the home.

The power management device provides information on whether the private power management system is linked to or independent of the power grid. A power management system, also known as HEMS (Home Energy Management System), is an information system that visualizes the amount of energy used in a home and the operating status so that the user can grasp it, enabling appropriate power management. may be part of As a specific aspect, as described in the embodiment, communicate with the power conditioner to monitor the power usage status of the system power grid, the storage battery, preferably the private power generator such as the solar power generator, and the electrical equipment in the house, Moreover, the HEMS controller which controls is mentioned. However, it is not limited to that aspect.

An electrical device is a device that operates by being supplied with power from a private power management system, and is a device that consumes power. Specific examples thereof include household appliances such as refrigerators, televisions, and air conditioners.
Furthermore, circuits in which these electric devices operate by consuming power supplied from a private power management system or grid power are collectively called operating circuits. When the grid interconnection state is the interconnected state, it may operate with the power supplied from the power system, or it may operate with the power supplied from the power supply device. Since no power is supplied from the electric power system when the grid connection state is independent, the device operates on the power supplied from the power supply device.

The switch circuit is a circuit that switches whether or not to supply power from the private power management system to the operating circuit.
On the other hand, the power supply device supplies power from the private power management system to those electric devices. Specific aspects thereof include, for example, a solar power generation device, a home power generation device such as a household fuel cell, and a device that supplies electric power from a storage battery. The solar cell module, the storage battery, and the power conditioner that controls the power thereof in the above-described embodiments correspond to the power supply device of the present invention.
Also, the control unit controls the operation of the electrical equipment. A specific aspect thereof is, for example, a configuration in which hardware resources of a control circuit centered on a microprocessor and control software executed by the microprocessor work together to realize control.

Furthermore, preferred embodiments of the present invention will be described.
(ii) When the value representing the grid-connected state is a value representing independence, the control unit may cause the operating circuit to perform a predetermined operation to notify the user that the grid-connected state is in the process of being independent. .
In this way, when the electric device is powered on, the user is notified that the grid connection state is independent, which is different from when the grid connection state is interconnected. The user can be made to notice that the power is out, and an appropriate response can be urged.

(iii) The control unit prevents the operating circuit from operating until it is notified that the grid connection state is in isolation, and after it has been notified that the grid connection state is in isolation. If an operation to cause a driving action is further received, the operating circuit may be made to perform the driving action even during the independence.
In this way, if an operation for performing a running operation is further received after performing a predetermined operation informing the user that the grid connection state is in an independent state, the electrical equipment can be operated even during a power outage. The electrical equipment can be operated as if it were confirmed to be the user's will.

(iv) If the value representing the grid interconnection state acquired by the communication circuit is a value representing independence, the control unit notifies that the grid interconnection state is being independent in addition to the operation or operates the power supply device. The notification of the state may be made to be performed by the operation circuit.
In this way, when the power of the electrical equipment is turned on, the electrical equipment is operated, and at the same time, it is notified that the grid connection is independent or the operation status of the power supply device is notified that the power is out. It can alert the user and encourage them to take appropriate action.

(v) If the value representing the grid-connected state acquired by the communication circuit is a value representing independence, the control unit selects a mode that consumes less power than the operating operation performed when the grid-connected state is interconnected. The operation circuit may be caused to perform the driving operation.
In this way, while the system interconnection state is independent, the operation can be performed in a mode that consumes less power than during interconnection, thereby saving power.

(vi) One aspect of the present invention provides a value representing a grid connection state of whether a private power management system including a power generation device or a power storage device is interconnected with a power grid or independent of the power grid. A power management device, a power supply device that supplies power generated by a power generation device or power stored by a power storage device, and a self-power management system that receives power from the power supply device when it is independent of the power system and generates self-power When the management system is interconnected with the power grid, it controls the operating circuits that receive power from the power grid or power supply equipment to operate, the switch circuits that turn on and off the power supply to the operating circuits, and the operating circuits. wherein the control unit communicates with the power management device to obtain a value representing the grid connection state when an operation to turn on the switch circuit is received, and the obtained grid connection state is It includes a private power management system that performs different controls depending on whether the values represent interconnected or independent.

Aspects of the present invention also include combinations of any of the aspects described above.
Various modifications of the present invention are possible in addition to the above-described embodiments. Those modifications should not be construed as not belonging to the scope of the present invention. The present invention should include all modifications within the scope of the claims, the meaning of equivalents, and the scope.

10: private power management system, 11: solar cell module, 12: power conditioner, 13: storage battery, 14: distribution board, 16: power monitor, 17: HEMS controller, 18: mobile communication terminal, 19: electrical equipment, 21: grid power network, 22: HEMS server, 41: control unit, 43: communication circuit, 45: operation circuit, 47: switch circuit, 49: power supply circuit, 51: remote controller, 53: display unit, 55: blackout message, 57: Blackout popup

Claims (6)

a communication circuit for acquiring from an external power management device a value representing a grid interconnection state of whether a private power management system including a power generation device or a power storage device is interconnected with a power grid or independent of the power grid;
When the private power management system is independent of the power system, power is supplied from a power supply device that supplies power generated or stored in the private power management system, and the private power management system is connected to the power system. an operation circuit that receives power from the power system or the power supply device and performs an operation when the system is connected;
a switch circuit for turning on and off power supply to the operating circuit;
A control unit that controls the operation circuit,
When receiving an operation to turn on the switch circuit, the control unit performs different control depending on whether the value representing the grid interconnection state acquired by the communication circuit is a value representing interconnection or a value representing independence. device. wherein, when the value representing the grid-connected state is a value representing independence, the control unit causes the operation circuit to perform a predetermined operation for informing a user that the grid-connected state is in the process of being independent. 1. The electrical equipment according to 1. The control unit prevents the operation circuit from performing the driving operation until it is notified that the system interconnection state is being independent, and notifies that the system interconnection state is being independent. 3. The electric device according to claim 2, wherein, after that, when an operation for performing said operation is further received, said operation circuit is made to perform said operation even during the independence. When the value representing the grid-connected state acquired by the communication circuit is a value representing independence, the control unit notifies that the grid-connected state is independent in addition to the operation or the power supply 4. The electrical equipment according to any one of claims 1 to 3, wherein the operating circuit is caused to notify the operating state of the device. When the value representing the grid-connected state acquired by the communication circuit is a value representing independence, the control unit selects a mode that consumes less power than the operating operation performed when the grid-connected state is interconnected. 5. The electrical equipment according to any one of claims 1 to 4, wherein the operating circuit is caused to perform a driving operation at a. A power management device that provides a value representing a grid interconnection state of whether a private power management system including a power generation device or a power storage device is interconnected with a power grid or independent of the power grid;
a power supply device that supplies power generated by the power generation device or power stored by the power storage device;
Power is supplied from the power supply device when the private power management system is independent of the power system, and from the power system or the power supply device when the private power management system is interconnected with the power system. An electric device including an operation circuit that receives power to operate, a switch circuit that turns on and off the power supply to the operation circuit, and a control unit that controls the operation circuit,
When receiving an operation to turn on the switch circuit, the control unit communicates with the power management device to acquire a value representing the grid interconnection state, and independently whether the acquired grid interconnection state is a value representing interconnection. A private power management system that controls the operation circuit to perform different operations depending on whether the value represents

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