JP2021061022A - Power management method and management device - Google Patents

Abstract

To provide a power rate management method, a user terminal, and a power rate management system that can improve convenience for a user.SOLUTION: A power rate management method includes: a terminal belonging to a user who belongs to a first facility receiving identification information for identifying a power meter that measures the electric energy consumed by or supplied from an apparatus belonging to the user (S13); the terminal transmitting the identification information to a server of a business operator that manages the charges for the supply of power from the apparatus (S14); when the apparatus is present in the first facility, a management device provided in the first facility receiving, from the server of the business operator, a first message instructing a reduction in the amount of power flow from an electric power system or a reduction in the amount of inverse power flow to the electric power system (S15); and even when the apparatus is present in a second facility different from the first facility, the management device transmitting, to the terminal, a second message instructing the start of adjustment of the amount of power consumed by or supplied from the apparatus, based on the first message (S20).SELECTED DRAWING: Figure 4

Description

The present invention relates to a power management method and a management device for flexibly managing a charge for power supply to a device or power supply from a device.

Conventionally, the electricity charge to be charged to the user is determined based on the amount of electric power measured by the electric power meter installed in the facility. As such a power meter, the introduction of a smart meter having a communication function is also being considered (for example, Patent Document 1).

Japanese Unexamined Patent Publication No. 2014-153337

By the way, in recent years, there are a wide variety of businesses involved in power supply, such as power generation businesses, power transmission and distribution businesses, and retail businesses. Under such a background, if the electricity charge can be charged only for each facility, the convenience of the user may be impaired.

Therefore, the present invention has been made to solve the above-mentioned problems, and an object of the present invention is to provide a power management method and a management device capable of improving user convenience.

The power charge management method according to the first feature is a step A in which the user terminal receives identification information for identifying a power meter for measuring the amount of power consumed or supplied by the device, and the user terminal is the device. Step B of transmitting the identification information to the server of the business operator who manages the charge for the power supply to or the power supply from the device, and the power meter by the server of the business operator based on the identification information. And step C to acquire the electric energy of the device from the watt-hour meter.

The user terminal according to the second feature is a receiving unit that receives identification information that identifies a power meter that measures the amount of power consumed or supplied by the device, and the user terminal supplies power to the device or said. It is provided with a transmission unit that transmits the identification information to the server of the business operator that manages the charge for the power supply from the device. The identification information is used to identify the watt hour meter on the server of the business operator.

The electric power charge management system according to the third feature includes a user terminal belonging to a user who uses the device, and a server of a business operator that manages a charge for supplying electric power to the device or supplying electric power from the device. The user terminal receives identification information that identifies a watt-hour meter that measures the amount of power consumed or supplied by the device. The user terminal transmits the identification information to the server of the business operator. The operator's server identifies the watt-hour meter based on the identification information, and acquires the amount of power measured by the watt-hour meter from the watt-hour meter.

According to one aspect, it is possible to provide a power management method and a management device that can improve the convenience of the user.

FIG. 1 is a diagram showing an electricity rate management system 100 according to an embodiment. FIG. 2 is a diagram showing a user terminal 10 according to the embodiment. FIG. 3 is a diagram showing a business operator server 200 according to the embodiment. FIG. 4 is a diagram showing an electricity rate management method according to an embodiment. FIG. 5 is a diagram showing an electricity rate management method according to the embodiment. FIG. 6 is a diagram showing an electricity rate management method according to the first modification. FIG. 7 is a diagram showing an electricity rate management method according to the second modification. FIG. 8 is a diagram showing an electricity rate management method according to the second modification.

Hereinafter, embodiments will be described with reference to the drawings. In the description of the drawings below, the same or similar parts are designated by the same or similar reference numerals.

However, it should be noted that the drawings are schematic and the ratio of each dimension is different from the actual one. Therefore, the specific dimensions should be determined in consideration of the following explanation. In addition, it goes without saying that the drawings include parts having different dimensional relationships or ratios from each other.

[Embodiment]
(Electricity rate management system)
Hereinafter, the electricity rate management system according to the embodiment will be described.

As shown in FIG. 1, the electricity rate management system 100 includes a business operator server 200 and a facility 300. In FIG. 1, facility 300A to facility 300C are exemplified as facility 300.

Each facility 300 is connected to the power system 110. In the following, the flow of electric power from the electric power system 110 to the facility 300 will be referred to as a power flow, and the flow of electric power from the facility 300 to the electric power system 110 will be referred to as reverse power flow.

The operator server 200 and the facility 300 are connected to the network 120. The network 120 may provide a line between the operator server 200 and the facility 300. The network 120 is, for example, the Internet. The network 120 may provide a dedicated line such as a VPN (Virtual Private Network).

The business operator server 200 is a server managed by a business operator such as a power generation business operator, a power transmission and distribution business operator, or a retail business operator. In the embodiment, the business operator server 200 is a business operator server that manages the power supply to the device 400 or the charge for the power supply from the device 400. The operator server 200 receives a power flow suppression message (DR; Demand Response) requesting suppression of the power flow from the power system 110 to the facility 300 and reverse power flow suppression requesting suppression of the reverse power flow from the facility 300 to the power system 110. A power suppression message containing at least one of the messages may be transmitted. The reverse power flow suppression message may be considered as an output suppression message instructing output suppression of the relay point 310.

Here, as the format of the power flow suppression message and the reverse power flow suppression message, an original format may be used, or a format compliant with automatic demand response (ADR; Automated Demand Response) may be used. Communication between the power management server 200 and the facility 300 may be performed by a method conforming to the Open ADR standard.

Facility 300 has a relay point 310 and a power meter 320. The relay point 310 is at least one of a feeding point for supplying electric power to the device 400 and a receiving point for receiving electric power from the device 400. The relay point 310 is, for example, an outlet to which a plug extending from the device 400 is connected. The relay point 310 may be omitted, or may be, for example, a charging plug when the device 400 is a vehicle (EV; Electric Vehicle) having a storage battery. The watt hour meter 320 measures the amount of power passing through the relay point 310 to which the device 400 is connected. The power meter 320 may be a current sensor connected to the relay point 310, or may be a smart meter provided in the facility 300.

The facility 300 may have at least one of a power load and a distributed power source in addition to the relay point 310 and the power meter 320. The electric power load is a home electric appliance or the like provided in the facility 300. Distributed power sources include solar cells, fuel cells, storage batteries, and the like.

Under such a premise, the usage scene according to the embodiment is as shown below. Specifically, when the user A belonging to the facility 300A is visiting the facility 300C, the usage scene in which power is supplied from the relay point 310C of the facility 300C to the device 400 belonging to the user A or the device 400 belonging to the user A Consider a usage scene in which power is supplied to the relay point 310C of the facility 300C. Therefore, the power meter 320C for measuring the amount of power passing through the relay point 310C is provided in the facility 300C different from the facility 300A to which the user A belongs. In such a usage scene, the user terminal 10 belonging to the user A is used to propose a method of managing the amount of power supplied to the device 400 or the charge for the power supply from the device 400 as the charge of the user A. The above-mentioned business server 200 is a server managed by a business contracting with user A.

Here, the user terminal 10 may have a function of communicating with the power meter 320C and the operator server 200. The user terminal 10 is, for example, a smartphone, a tablet terminal, a personal computer, or the like. The device 400 may be a device that uses the electric power supplied from the relay point 310, or may be a device that supplies electric power to the relay point 310. The type of the device 400 is not particularly limited, but it may be a vehicle having a storage battery, a mobile terminal such as a laptop computer or a smartphone, or a load device such as a television or a refrigerator. The device 400 may have the function of the user terminal 10.

(User terminal)
Hereinafter, the user terminal according to the embodiment will be described. As shown in FIG. 2, the user terminal 10 has a communication unit 11 and a control unit 12. The user terminal 10 is a terminal belonging to the user A who uses the device.

The communication unit 11 is composed of a communication module, and communicates with the power meter 320 and the operator server 200. For example, the communication unit 11 receives the identification information for identifying the power meter 320 from the power meter 320, and the identification information for identifying the power meter 320 (for example, the contractor ID, the manufacturer code, the position information, the manufacturing code, or a combination thereof). (Character string, etc.) is transmitted to the operator server 200.

In the embodiment, the communication unit 11 receives the identification information from the power meter 320 in the area where the power meter 320 is provided. The area where the watt-hour meter 320 is provided may be an effective area of the wireless LAN to which the watt-hour meter 320 is connected (that is, the wireless LAN provided in the facility 300). The area where the power meter 320 is provided may be an effective area for short-range wireless communication in the case where the power meter 320 supports short-range wireless communication.

The control unit 12 is composed of a memory, a CPU, and the like, and controls each configuration provided in the user terminal 10.

(Business server)
Hereinafter, the business operator server 200 according to the embodiment will be described. As shown in FIG. 3, the operator server 200 has a communication unit 210, a database 220, and a control unit 230.

The communication unit 210 is composed of a communication module and communicates with the user terminal 10. The communication unit 210 may communicate with the power meter 320. For example, the communication unit 210 receives the identification information for identifying the power meter 320 from the user terminal 10, and receives the electric energy from the power meter 320 via the relay point 310 to which the device 400 is connected.

The database 320 is composed of a non-volatile memory and / and a storage medium such as an HDD, and manages a charge for supplying power to the device 400 or supplying power from the device 400. For example, the database 320 manages user information that identifies the user A, the amount of power that passes through the relay point 310 to which the device 400 is connected, and charge information that specifies the charge for the amount of power.

The control unit 230 is composed of a memory, a CPU, and the like, and controls each configuration provided in the operator server 200. For example, the control unit 230 identifies a power meter 320 that measures the amount of power passing through the relay point 310 to which the device 400 is connected, based on the identification information received from the user terminal 10. The control unit 230 acquires the amount of electric power passing through the relay point 310 from the specified electricity meter 320.

(Electricity rate management method)
Hereinafter, the electricity rate management method according to the embodiment will be described. Here, when the user A belonging to the facility 300A is visiting the facility 300C, a usage scene in which power is supplied from the relay point 310C of the facility 300C to the device 400 belonging to the user A will be considered.

First, a sequence for starting power supply to the device 400 from the relay point 310C will be described.

As shown in FIG. 4, in step S11, the user A belonging to the facility 300A visits the facility 300C.

In step S12, the user terminal 10 transmits a message (ID request) requesting identification information for identifying the power meter 320C to the power meter 320C.

In step S13, the user terminal 10 receives a message (ID response) indicating identification information for identifying the power meter 320C from the power meter 320C (step A).

In step S14, the user terminal 10 transmits a message (start application) requesting the start of use of the relay point 310C to the operator server 200. The message includes identification information that identifies the electricity meter 320C (step B). As a result, the operator server 200 identifies the power meter 320C of the facility 320C used by the user A. In addition, the message may include user information that identifies user A. As a result, the business server 200 identifies the user information that identifies the user A.

In step S15, the operator server 200 transmits a message (status request) requesting the status confirmation of the watt-hour meter 320C to the watt-hour meter 320C.

In step S16, the operator server 200 receives a message (state response) indicating the state of the power meter 320C (for example, the meter value of the power meter 320C, the open / closed state of the breaker of the relay point 310C) from the power meter 320C.

In step S17, the operator server 200 determines whether or not the power supply to the device 400 can be started from the relay point 310C. For example, the operator server 200 determines whether or not the breaker at the relay point 310C is in the closed state based on the open / closed state of the breaker at the relay point 310C, and supplies power to the device 400 based on the meter value of the power meter 320C. Judge whether or not there is spare capacity. When the power supply to the device 400 can be started from the relay point 310C, the operator server 200 transmits a message (start instruction) instructing the start of the power supply to the device 400 to the power meter 320C. Such a message may be an instruction to open the breaker at the relay point 310C.

In step S18, the operator server 200 transmits a message (start permission) permitting the start of power supply to the device 400 to the user terminal 10.

In step S19, power supply to the device 400 starts from the relay point 310C.

In step S20 and step S21, the operator server 200 acquires the meter value of the power meter 320C and the open / closed state of the breaker of the relay point 310C by transmitting the state request and receiving the state response. The meter value and the open / closed state of the breaker may be acquired periodically.

Secondly, a sequence for stopping the power supply from the relay point 310C to the device 400 will be described.

As shown in FIG. 5, in step S31, power is supplied from the relay point 310C to the device 400.

In step S32 and step S33, the operator server 200 acquires the meter value of the power meter 320C and the open / closed state of the breaker of the relay point 310C by transmitting the state request and receiving the state response. The meter value and the open / closed state of the breaker may be acquired periodically.

In step S34, the user terminal 10 transmits a message (suspension application) requesting suspension of use of the relay point 310C to the operator server 200.

In step S35 and step S36, the operator server 200 acquires the meter value of the power meter 320C and the open / closed state of the breaker of the relay point 310C by transmitting the state request and receiving the state response.

In step S37, the operator server 200 determines whether or not the power supply to the device 400 from the relay point 310C can be stopped. For example, the operator server 200 determines, based on the meter value of the electricity meter 320C, whether or not the suspension of the power supply to the device 400 adversely affects the power supply-demand balance of the power system 110 and the facility 300C. When the power supply to the device 400 can be stopped from the relay point 310C, the operator server 200 transmits a message (stop instruction) instructing the stop of the power supply to the device 400 to the power meter 320C. Such a message may be an instruction to close the breaker at the relay point 310C.

In step S38, the business operator server 200 transmits a message (stop permission) permitting the stop of the power supply to the device 400 to the user terminal 10.

In step S39, the power supply from the relay point 310C to the device 400 is stopped.

In step S40, the operator server 200 performs post-processing related to power supply to the device 400. For example, the operator server 200 acquires the amount of power (power supply amount) via the relay point 310C by periodically receiving (monitoring) the meter value of the power meter 320C (step C). The business operator server 200 manages the specified power supply amount in association with the user information that identifies the user A.

In FIGS. 4 and 5, a usage scene in which power is supplied from the relay point 310C of the facility 300C to the device 400 belonging to the user A has been described. However, the embodiment is not limited to this. The sequence shown in FIGS. 4 and 5 can also be applied to a usage scene in which power is supplied from the device 400 belonging to the user A to the relay point 310C of the facility 300C.

(Action and effect)
In the embodiment, the user terminal 10 receives the identification information for identifying the power meter 320 from the power meter 320, and transmits the identification information for identifying the power meter 320 to the operator server 200. Therefore, the operator server 200 can specify the watt-hour meter 320 that measures the amount of electric power passing through the relay point 310 to which the device 400 is connected at the visited destination, and appropriately charges the amount of electric power passing through the relay point 310. Can be managed.

[Change example 1]
Hereinafter, modification 1 of the embodiment will be described. In the following, the differences from the embodiments will be mainly described.

In the embodiment, the power supply from the relay point 310C to the device 400 is stopped in response to the stop request transmitted from the user terminal 10. On the other hand, in the first modification, the power supply from the relay point 310C to the device 400 is stopped when a certain time elapses after the power supply from the relay point 310C to the device 400 starts.

(Electricity rate management method)
Hereinafter, the electricity rate management method according to the change example 1 will be described. In FIG. 6, the same step numbers are assigned to the same processes as in FIG. The same process as in FIG. 5 will be omitted.

As shown in FIG. 6, the operator server 200 has a timer that measures the elapsed time from the start of power supply to the device 400 from the relay point 310C. The operator server 200 performs the processes of steps S37 and S38 described above according to the expiration of the timer (elapsed of a certain time).

[Change example 2]
Next, modification 2 of the embodiment will be described. In the following, the differences from the embodiments will be mainly described.

In the second modification, when the user A belonging to the facility 300A is visiting the facility 300C and the power is supplied from the relay point 310C to the device 400 or the power is supplied from the device 400 to the relay point 310C. Consider a usage scene in which the suppression of tidal flow or the suppression of reverse power flow is instructed.

In such a usage scene, the user terminal 10 receives a message instructing the suppression of the tidal flow from the power system 110 or the suppression of the reverse power flow to the power system 110. For example, the user terminal 10 receives a message from a power management device (EMS; Energy Management System) provided in the facility 300A to which the user A belongs. In the following, the EMS provided in the facility 300A will be referred to as EMS330A.

The user terminal 10 acquires information for specifying the suppressed power amount suppressed by the device 400 from the power meter 320 during the suppression period of the tide flow or reverse power flow, and transmits the information for specifying the suppressed power amount. To do. The user terminal 10 may transmit information for specifying the suppressed power amount to the EMS 330A. The user terminal 10 may transmit information for specifying the suppressed power amount to the operator server 200.

For example, the information for specifying the suppressed power amount is the meter value of the power meter 320. The amount of power passing through the relay point 310 during the tide flow or reverse power flow suppression period is specified by the meter value of the power meter 320. Therefore, the amount of suppressed power suppressed by the device 400 is specified by comparing the amount of power passing through the relay point 310 before the suppression period with the amount of power passing through the relay point 310 during the suppression period.

(Electricity rate management method)
Hereinafter, the electricity rate management method according to the second modification will be described. Here, when the user A belonging to the facility 300A is visiting the facility 300C, a usage scene in which power is supplied from the relay point 310C of the facility 300C to the device 400 belonging to the user A will be considered. Here, a case where the tidal flow from the power system 110 to the facility 300 is suppressed will be illustrated.

First, a sequence for starting the suppression of the tidal current will be described.

As shown in FIG. 7, in step S51, power is supplied from the relay point 310C to the device 400.

In step S52, the operator server 200 transmits a tidal current suppression message (DR; Demand Response) requesting suppression of the tidal current from the power system 110 to the facility 300 to the EMS 330A.

In step S53, EMS330A formulates a supply and demand plan. The supply and demand plan may be a plan to reduce the power consumption of the power load provided in the facility 300A, or a plan to increase the output of the distributed power source provided in the facility 300A.

In step S54, the EMS 330A transmits a message (adjustment start instruction) instructing the start of reduction of the power consumption of the device 400 to the user terminal 10.

In step S55, the user terminal 10 transmits a message (start response) indicating that the power consumption of the device 400 is to be reduced to the EMS 330A.

In step S56, the user terminal 10 transmits a message (meter value request) requesting the meter value of the power meter 320C to the power meter 320C.

In step S57, the user terminal 10 receives a message (meter value response) indicating the meter value of the power meter 320C from the power meter 320C. The meter value of the power meter 320C is a meter value at the start timing of the suppression period.

In step S58, the user terminal 10 transmits the meter value of the power meter 320C (the meter value at the start timing of the suppression period) to the EMS 330A.

In step S59, the device 400 starts power suppression. That is, the power consumption of the device 400 is reduced.

In FIG. 7, the power suppression state (tide flow suppression state) is described as step S60 for convenience of explanation to clarify the point that the power suppression is performed.

Secondly, a sequence for ending the suppression of the tidal current will be described.

In FIG. 8, for convenience of explanation for clarifying the point that the power suppression is performed, the power suppression state (tide flow suppression state) is described as step S71.

As shown in FIG. 8, in step S72, the EMS 330A transmits a message (adjustment end instruction) instructing the end of reduction of the power consumption of the device 400 to the user terminal 10.

In step S73, the user terminal 10 transmits a message (end response) indicating that the reduction of the power consumption of the device 400 is finished to the EMS 330A.

In step S74, the user terminal 10 transmits a message (meter value request) requesting the meter value of the power meter 320C to the power meter 320C.

In step S75, the user terminal 10 receives a message (meter value response) indicating the meter value of the power meter 320C from the power meter 320C. The meter value of the power meter 320C is a meter value at the end timing of the suppression period.

In step S76, the user terminal 10 transmits the meter value of the power meter 320C (the meter value at the end timing of the suppression period) to the EMS 330A.

In step S77, the device 400 ends the power suppression. That is, the power consumption of the device 400 is increased (returning to the power consumption before the suppression period).

In step S78, the EMS330A aggregates the tidal flow suppression results during the suppression period. For example, the EMS330A aggregates the tidal currents suppressed at the facility 300A.

Here, the EMS 330A may total the amount of power passing through the relay point 310 during the suppression period based on the meter values received in steps S58 and S76. Further, when the EMS 330A knows the amount of power passing through the relay point 310 before the suppression period, the amount of power passing through the relay point 310 before the suppression period and the amount of power passing through the relay point 310 during the suppression period. By comparison with, the suppressed power amount suppressed by the device 400 may be totaled.

In step S79, the EMS 330A transmits the aggregation result of step S78 to the operator server 200.

In FIGS. 7 and 8, a usage scene in which power is supplied from the relay point 310C of the facility 300C to the device 400 belonging to the user A has been described. However, the embodiment is not limited to this. The sequence shown in FIGS. 7 and 8 can also be applied to a usage scene in which power is supplied from the device 400 belonging to the user A to the relay point 310C of the facility 300C. In such a case, the power suppression may be the suppression of reverse power flow.

[Other Embodiments]
Although the present invention has been described by embodiments described above, the statements and drawings that form part of this disclosure should not be understood to limit the invention. Various alternative embodiments, examples and operational techniques will be apparent to those skilled in the art from this disclosure.

In the embodiment, the operator server 200 specifies the amount of electric power passing through the relay point 310C by periodically receiving (monitoring) the meter value of the electric power meter 320C. However, the embodiment is not limited to this. For example, the operator server 200 passes through the relay point 310C by receiving the meter value of the power meter 320C from the power meter 320C at the start timing and the end timing of the power supply to the device 400 or the power supply from the device 400. You may specify the amount of power to be used. Alternatively, the power meter 320C is configured to measure the amount of power passing through the relay point 310C, and the operator server 200 may receive information indicating the amount of power passing through the relay point 310C from the power meter 320C. Good.

In the second modification, the meter value of the electricity meter 320C is transmitted to the user terminal 10 and the EMS330A, and the aggregation result generated based on the meter value is transmitted from the EMS330A to the operator server 200. However, the second modification is not limited to this. The meter value of the watt-hour meter 320C may be transmitted from the watt-hour meter 320C to the operator server 200. In such a case, the suppressed power amount suppressed by the device 400 is totaled by the operator server 200.

In the second modification, the EMS 330A may determine whether or not the device 400 is present in the facility 300A. For example, whether or not the device 400 exists in the facility 300A may be determined by whether or not the device 400 is connected to the relay point 310A of the facility 300A. When the device 400 has a communication function, whether or not the device 400 exists in the facility 300A may be determined by whether or not the device 400 is connected to the wireless LAN provided in the facility 300A. The EMS 330A may constantly monitor whether the device 400 is present at the facility 300A.

Although not particularly mentioned in the embodiment, the meter value of the power meter 320 may be a parameter of any one or more of the power value, the frequency, and the voltage value.

10 ... user terminal, 11 ... communication unit, 12 ... control unit, 100 ... electricity rate management system, 110 ... power system, 120 ... network, 200 ... operator server, 210 ... communication unit, 220 ... database, 230 ... control unit , 300 ... facility, 310 ... relay point, 320 ... electricity meter, 400 ... equipment

Claims (7)

Step A in which the terminal belonging to the user belonging to the first facility receives the identification information identifying the power meter for measuring the amount of power consumed or supplied by the device belonging to the user.
Step B in which the terminal transmits the identification information to the server of the business operator that manages the charge for the power supply from the device.
When the device is present in the first facility, the management device provided in the first facility sends a first message instructing the suppression of the tide flow from the power system or the suppression of the reverse power flow to the power system. Step C received from the server of the operator and
Even when the device exists in a second facility different from the first facility, the management device instructs the start of adjustment of the amount of power consumed or supplied by the device based on the first message. A power management method comprising step D of transmitting a second message to the terminal. The device is a vehicle
Whether or not the device is connected to the charging plug of the first facility or whether or not the device is connected to the radio of the first facility determines whether or not the device exists in the first facility. The power management method according to claim 1, further comprising the step of performing. A step in which the terminal receives the first meter value at the start timing of the suppression period from the power meter provided in the second facility based on the second message.
The power management method according to claim 1 or 2, further comprising a step in which the terminal transmits the first meter value to the management device. A step in which the device adjusts the amount of power consumed or supplied by the device.
A step in which the management device transmits a third message instructing the end of adjustment of the amount of electric power consumed or supplied by the device to the terminal.
A step in which the terminal receives a second meter value at the end timing of the suppression period from the power meter provided in the second facility based on the third message.
The power management method according to claim 3, further comprising a step in which the terminal transmits the second meter value to the management device. A step in which the management device aggregates the amount of suppressed power suppressed by the device based on the first meter value and the second meter value from the terminal.
The power management method according to claim 4, further comprising a step in which the management device transmits the result of the aggregation to the server of the business operator. It is a management device installed in the first facility.
When a device belonging to a user belonging to the first facility exists in the first facility, the device sends a first message instructing the suppression of the tide flow from the power system or the suppression of the reverse power flow to the power system. The receiver that receives from the server of the operator that manages the charge for the power supply from
Even when the device exists in a second facility different from the first facility, a second message instructing the start of adjustment of the amount of power consumed or supplied by the device is sent based on the first message. A management device including a transmission unit that transmits to a terminal belonging to the user. Step A in which the terminal belonging to the user belonging to the first facility receives the identification information identifying the power meter for measuring the amount of power consumed or supplied by the device belonging to the user.
Step B in which the terminal transmits the identification information to the server of the business operator that manages the charge for the power supply from the device.
Step C, in which the management device provided in the first facility determines whether or not the device exists in the first facility,
Step D, in which the management device receives a first message instructing the suppression of the tide flow from the power system or the suppression of the reverse power flow to the power system from the server of the business operator,
Even when the device exists in a second facility different from the first facility, a second message instructing the management device to start adjusting the amount of power consumed or supplied by the device is transmitted to the terminal. A power management method comprising the step E to be performed.

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