JP2015219202A - Watthour meter, watthour measuring system and watthour measuring method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To measure a selling power amount per user unit.SOLUTION: The watthour meter measures an electric power amount as a selling power amount, which is supplied to a power distribution network in a facility from an electric power supply unit which is connected to an electric outlet in the facility via the electric outlet. A user authentication is required to an external system which includes at least the facility watthour meter to acquire the user authentication result from the facility watthour meter, and based on the result, the output from the electric power supply unit is controlled.

Description

  The present invention relates to a technique for measuring the amount of power sold to sell power to a commercial power supply system.

  In recent years, distributed power sources such as solar power generation systems have been installed in facilities such as homes, and the power generated by distributed power sources is supplied to the load in the facility in parallel with the commercial power source, and the surplus is reversed to the commercial power system. A mechanism for selling power by flowing power is becoming widespread (for example, Patent Document 1).

JP 2011-095059 A

By the way, in recent years, development of various power generators and storage batteries that can be easily owned by individuals has progressed. For this reason, in addition to selling power to the commercial power supply system in units of facilities such as homes, there is a possibility that a society in which power is sold in units of users will appear. When such a society emerges, a mechanism that enables power sales in units of users is required.
Therefore, an object of the present invention is to provide a watt-hour meter that enables power sale in units of users.

  The watt-hour meter according to the present invention is a watt-hour meter for measuring the amount of power sold by a user, and is supplied to a distribution network in the facility from the power supply device connected to the outlet in the facility through the outlet. A measurement unit that measures the amount of electric power to be sold as the amount of electric power sold, a control unit that controls the output of the power supply device, and an amount of electric power exchanged between a commercial power supply system and a distribution line in the facility A communication unit that communicates with an external system including at least an energy meter for facilities, and the communication unit notifies the external system of user information for specifying a user who performs the power sale, and A result of user authentication based on user information is acquired from the external system, and the control unit performs power output control of the power supply device based on the result of user authentication.

  With the watt-hour meter according to the present invention, it is possible to measure the amount of power sold for each user.

1 is a configuration diagram of a power sale system 1 according to Embodiment 1. FIG. An example of the information memorize | stored in the electric power sale electric energy storage part 120 of the electric power sale meter 100. FIG. An example of the registration information of the power sale meter which the server 300 holds. The sequence diagram which shows the outline | summary of the whole operation | movement of the power sale system 1. FIG. The flowchart which shows operation | movement of the power sale meter 100. FIG. The flowchart which shows the operation | movement regarding the power sale of the facility meter 200. FIG. The flowchart which shows the verification operation | movement by the verification part 250 of the facility meter 200. FIG. FIG. 3 is a configuration diagram of a power sale system 1A in a first modification of the first embodiment. FIG. 6 is a schematic diagram of a power sale system 1B in a second modification of the first embodiment. The block diagram of the power sale system 2 in Embodiment 2. FIG. The sequence diagram which shows the outline | summary of the whole operation | movement of the power sale system 2. FIG. The flowchart which shows operation | movement of the power sale meter 500. FIG. The flowchart which shows the operation | movement regarding the power sale of the facility meter 600. FIG. The block diagram of the power sale system 2A in Embodiment 2A. The sequence diagram which shows the outline | summary of the whole operation | movement of the power sale system 2A. The flowchart which shows operation | movement of the power sale meter 1500. The flowchart which shows the operation | movement regarding the power sale of the facility meter 1600. FIG. The flowchart which shows the verification operation | movement by the authentication verification part 1610 of the facility meter 1600. FIG. (A) And (b) The figure explaining an example of the verification by the authentication verification part 1610 of the facility meter 1600. FIG. FIG. 6 is a configuration diagram of a power sale system 3 in a third embodiment. The sequence diagram which shows the outline | summary of the whole operation | movement of the power sale system 3. FIG. The flowchart which shows operation | movement of the power sale meter 700. FIG. The flowchart which shows the operation | movement regarding the power sale of the facility meter 800. FIG. The flowchart which shows the verification operation | movement by the verification part 820 of the facility meter 800. The block diagram of the power sale system 4 in Embodiment 4. FIG. An example of the information memorize | stored in the memory | storage part 1030 of the facility meter 1000. The sequence diagram which shows the outline | summary of the whole operation | movement of the power sale system 4. FIG. The flowchart which shows operation | movement of the power sale meter 900. FIG. The flowchart which shows the operation | movement regarding the power sale of the facility meter 1000. FIG. The figure explaining the conventional electricity sales meter.

≪Examination until the invention≫
As described above, the inventors consider that there may be a society where power is sold in units of users in addition to selling power to the commercial power supply system in units of facilities such as homes. It came. And he thought that the power from the power supply could be output to an outlet provided in the facility to sell electricity.

Therefore, the inventors examined a problem in the case of selling power in units of users through an outlet with reference to a general power selling system as shown in FIG.
In FIG. 30, the solar power generation system 10 is provided in the power distribution network upstream of the distribution board 20, and the trading power meter 30 is provided in the power distribution network upstream of the solar power generation system 10. Thereby, the electric energy sales meter 30 can measure both the amount of electric power purchased and the amount of electric power sold by the electric power purchase amount measurement part 31 and the electric power sale electric energy measurement part 32 with which it is provided.

  By the way, in the system configuration of FIG. 30, when the power of a power supply device such as a generator or a storage battery is output to the outlet, the output power is transmitted to the facility load group 40 provided downstream of the distribution board 20. It is assumed that it will be consumed. In such a case, since the trading power meter 30 is provided in the distribution network upstream of the distribution board 20, the trading power provided at the position of FIG. It came to the subject that it cannot measure correctly with the quantity meter 30.

As a result of studying this problem, the inventors have recognized the necessity of directly measuring the amount of power output from the power supply device to the outlet, and new power is provided between the outlet and the power supply device that outputs power to the outlet. The knowledge that it was necessary to install a meter was obtained.
Furthermore, the inventors examined a problem when a new watt-hour meter is provided between an outlet and a power supply device that outputs electric power to the outlet.

  The number of users who sell power via a certain outlet is not limited to one, and the manager of the commercial power supply system does not always accept power from anyone. For this reason, the inventors grasp who the power is sold by the manager of the commercial power supply system at the start of the power sale through the outlet, and output control of the power supply device is performed according to the result of the grasp. They learned that the amount of power sold needs to be managed.

  Further, since the new watt-hour meter is provided between the outlet and the power supply device that outputs power to the outlet, it is assumed that the new watt-hour meter is managed by the individual. For this reason, there is a possibility that the new watt-hour meter may be used illegally, for example, by tampering with the measured value of the power sale power amount and inflating the power sale power amount. On the other hand, the electric power meter 30 for sale in FIG. 30 is generally installed in the distribution network of the facility at the time of construction of the facility and is managed by the manager of the commercial power supply system, so that fraud is not easily performed.

In addition, as described above, the trading electric energy meter 30 in FIG. 30 cannot accurately measure the amount of power output to the outlet, but the amount of power supplied to the facility from the commercial power system and the commercial power from the facility By grasping the amount of power supplied to the power supply system, the amount of power output to the outlet can be estimated to some extent.
Therefore, the inventors combined a new watt-hour meter managed by an individual and a watt-hour meter such as the buying and selling watt-hour meter 30 shown in FIG. We obtained knowledge that fraud using sapphire can be suppressed.

Hereinafter, in the embodiment and the modification, a watt hour meter in view of the above-described knowledge will be described.
<< 1. Embodiment 1 >>
In the first embodiment, a power sale energy meter (a power sale meter) is provided between an outlet and a power supply device that outputs power to the outlet, and measures the amount of power output from the power supply device to the outlet as the amount of power sold. Will be described. In addition, the power sale meter according to the first embodiment asks the facility watt-hour meter (facility meter) provided in the power distribution network upstream of the facility outlet for authentication to start power sale. Then, when the facility meter recognizes the start of power sale, the power is output to the power supply device and the power sale is started. The power sale meter according to the first embodiment notifies the facility meter of the measurement result of the power sale power amount, and the facility meter verifies whether or not the notified measurement result of the power sale electricity meter is reliable.

Hereinafter, the power sale meter of Embodiment 1 is demonstrated, referring drawings.
<1-1. Configuration>
FIG. 1 is a configuration diagram of a power sale system 1 including a power sale meter 100 according to the first embodiment.
A power sale system 1 shown in FIG. 1 includes a power supply device 11, a power sale meter 100, a facility meter 200, and a server 300.

In the power selling system 1, the user outputs power from the power supply device 11 to the outlet 50 of the facility, and supplies power to the commercial power supply system to sell power.
The power supply device 11 has a function of outputting an alternating current that satisfies a regulation for causing a commercial power system to reversely flow. The power supply device 11 is connected to the power supply device terminal 160 of the power sale meter 100 through a terminal 12 provided on the power supply device 11, and the output power of the power supply device 11 is supplied to the distribution line of the facility via the power sale meter 100 and the outlet 50. Supplied.

Further, the power supply device 11 has a function of turning on / off the power output in accordance with control of the control unit 140 of the power sale meter 100 described later. For example, a power generator or a storage battery system is used for the power supply device 11.
The power sale meter 100 includes a power sale power amount measurement unit 110, a power sale power amount storage unit 120, a facility meter communication unit 130, a control unit 140, an outlet terminal 150, and a power supply terminal 160.

The power sale meter 100 is provided between the outlet 50 and the power supply device 11, connected to the outlet 50 through the outlet terminal 150, and connected to the terminal 12 of the power supply device 11 through the power supply terminal 160.
The power sale power amount measurement unit 110 has a function of measuring the amount of power output from the power supply device 11 to the outlet 50 as the power sale power amount and outputting the measurement result to the power sale power amount storage unit 120.

The power sale power amount storage unit 120 has a function of storing the measurement result of the power sale power amount output from the power sale power amount measurement unit 110.
FIG. 2 is an example of a measurement result of the power sale power amount stored in the power sale power amount storage unit 120.
The power sale power amount storage unit 120 shown in FIG. 2 includes items of “power supply device ID”, “power sale date and time”, and “power sale power amount”, and the date and time when the power sale was performed for each power supply device and the power sale power. I remember my ability.

The facility meter communication unit 130 has a function of communicating with a power sale meter communication unit 230 of the facility meter 200 described later.
Specifically, the facility meter communication unit 130 notifies the power sale meter communication unit 230 of an ID unique to the power sale meter 100 for identifying the power sale meter 100.
The ID of the power sale meter 100 is information used for authentication of the start of power sale (start of power output of the power supply device 11) performed on the facility meter side. The user who performs electricity is specified.

Further, the inter-facility meter communication unit 130 specifically acquires an authentication result of the start of power sale, notification of a measurement result of the power sale power amount by the power sale power amount measurement unit 110, acquisition of a report on whether or not the power sale is established, etc. I do.
For example, wireless communication or PLC is used as the communication means of the facility meter communication unit 130 and the power sale meter communication unit 230.

The control unit 140 has a function of controlling on / off of the power output of the power supply apparatus 11 according to the authentication result of the start of power sale output from the facility meter communication unit 130.
Specifically, when the notification of permission to start power sale is acquired by the facility meter inter-communication unit 130, the control unit 140 performs on-control that causes the power supply device 11 to output power, and does not permit power sale start. When the notification is acquired, off control is performed so that the power supply device 11 does not output power.

The facility meter 200 includes a received power amount measuring unit 210, a reverse power flow energy measuring unit 220, a power selling meter communication unit 230, an authentication unit 240, a verification unit 250, an inter-network communication unit 260, and a storage unit. 270.
The facility meter 200 is provided upstream of the distribution board 20 in the distribution line of the commercial power system.

The received power amount measurement unit 210 has a function of measuring the amount of power supplied to the facility from the commercial power supply system, in other words, the received power amount received by the facility from the commercial power source.
The reverse power flow amount measuring unit 220 has a function of measuring the amount of power supplied from the facility side to the commercial power supply system, in other words, the reverse power flow power amount reversely flowing in the distribution lines of the commercial power supply system.

Of course, the received power amount measuring unit 210 and the reverse power flow amount measuring unit 220 may be implemented as one configuration for measuring the bidirectional power amount.
The power sale meter communication unit 230 has a function of communicating with the facility meter communication unit 130 of the power sale meter 100.
Specifically, the power sale meter communication unit 230 acquires the ID of the power sale meter 100, notifies the authentication result of the start of power sale by the authentication unit 240, acquires the measurement result of the power sale power amount, and establishes power sale.・ Notify the failure report.

The authentication unit 240 has a function of authenticating the start of power sale based on the ID of the power sale meter 100 acquired by the communication unit 230 between power sale meters.
Specifically, the authentication unit 240 inquires of the server 300 whether or not the power sale meter 100 corresponding to the ID is registered via the inter-network communication unit 260 and the network 60. If the power sale meter 100 corresponding to the ID is registered, the start of power sale is permitted, and if not registered, the start of power sale is not permitted.

The verification unit 250 has a function of verifying whether or not the measurement result of the amount of power sold by the power sale meter 100 acquired by the power sale meter communication unit 230 is reliable. Details of the verification method are described in <1-2. Operation> will be described later.
The inter-network communication unit 260 has a function of communicating with the server 300 via the network 60.

Specifically, the inter-network communication unit 260 mediates between the server 300 and the authentication unit 240 when the authentication unit 240 makes an inquiry regarding the authentication of the start of power sale. In addition, the server 300 is notified of the verification result of the verification unit 250 and the amount of electric power sold stored in the storage unit 270.
The storage unit 270 stores the measurement result of the received power amount measurement unit 210 and the measurement result of the reverse power flow amount measurement unit 220, and the measurement result of the power sale power amount acquired by the inter-power sale meter communication unit 230. Has a function of storing.

The server 300 is a server device that manages power sales through the power sales meter 100.
The server 300 has a function of communicating with the facility meter 200 via the network 60. Specifically, a notification of a power sale report via the power sale meter 100 is acquired from the facility meter 200.
In addition, the server 300 has a function of storing registration information of the power sale meter 100. FIG. 3 is an example of registration information of the power sale meter 100 owned by the server 300. In the information illustrated in FIG. 3, identification information of the power sale meter 100 and identification information of a power sale user who performs power sale using the power sale meter 100 are stored in association with each other.

  Further, the server 300 has a function of receiving an inquiry from the authentication unit 240 of the facility meter 200 and answering the inquiry. Specifically, for example, the notification of the ID of the power sale meter 100 is received from the authentication unit 240 of the facility meter 200, and the power sale meter 100 corresponding to the notified ID is referred to by referring to the registration information of the power sale meter 100. Check if it is registered and reply.

<1-2. Operation>
FIG. 4 is a sequence diagram showing the overall operation of the power sale system 1.
The facility meter 200 constantly measures and stores the amount of received power and the amount of reverse power flow (S0). The measurement results of the received power amount and the reverse power flow energy amount are used in the verification process (S7) in the verification unit 250.

When the power sale meter 100 receives a request to start selling power from the power supply device 11, the power sale meter 100 notifies the facility meter 200 of the ID of its own device (S1).
In response, the facility meter 200 authenticates the start of power sale via the power sale meter 100 using the ID of the power sale meter 100 notified in step S1 (S2). Then, the authentication result of step S2, that is, permission or non-permission of power sale start is notified (S3).

  In response to this, the power sale meter 100 causes the power supply device 11 to output power if the authentication result of the power sale start notified in step S3 is affirmative (S4). And the electric energy output from the power supply device 11 is measured and memorize | stored as electric power sales electric energy (S5). When the power output from the power supply device 11 is finished, the facility meter 200 is notified of the measurement result of the amount of power sold in step S5 (S6).

  In response to this, the facility meter 200 verifies whether or not the measurement result of the power sale power amount notified in step S6 is reliable (S7). And according to the verification result of step S7, the power sale is reported to the server 300 (S8). Specifically, if the verification result is affirmative, the server 300 is notified of the power sale power amount measurement result as a power sale report. On the other hand, if the verification result is negative, the server 300 is notified of the possibility of malfunction of the power sale meter 100, for example, as a power sale report. Then, after step S8, the power sale meter 100 is notified of the establishment or non-establishment of power sale according to the verification result of step S7 (S9).

In response to this, the power sale meter 100 notifies the user of the establishment or non-establishment of the power sale (S10).
Next, specific operations of the power sale meter 100 and the facility meter 200 will be described.
FIG. 5 is a flowchart showing the operation of the power sale meter 100.

First, when the power sale meter 100 receives a request to start power sale from the power supply device 11, the facility meter communication unit 130 notifies the power meter communication unit 230 of the facility meter 200 of the ID of its own device (S101). ). This ID is used for authentication of the start of power sale by the facility meter 200 side.
Subsequently, the inter-facility meter communication unit 130 acquires the authentication result of the start of power sale from the inter-power sale meter communication unit 230 of the facility meter 200 and outputs it to the control unit 140 (S102).

Subsequently, if the authentication result of the power sale start is negative (S103: NO), the control unit 140 notifies the user that the power sale start is not permitted and ends the process (S104). On the other hand, if the authentication result of the power sale start is positive (S103: YES), the power supply device 11 is caused to output power (S105).
When power is output from the power supply device 11 in step S105, the power sale power amount measurement unit 110 measures the power amount output from the power supply device 11 as the power sale power amount and stores it in the power sale power amount storage unit 120 (S106). ). Until the power output by the power supply device 11 is completed, the process of step S106 is repeated (S107: NO).

When the power output by the power supply device 11 ends (S107: YES), the facility meter communication unit 130 notifies the power sale power amount measurement result of step S106 to the power sale meter communication unit 230 of the facility meter 200. (S108).
In response to this, the facility meter 200 verifies whether or not the measurement result of the power sale power amount notified in step S108 is reliable, and determines whether the power sale is established or not according to the verification result. Then, the inter-facility meter communication unit 130 acquires a notification of establishment or non-establishment of power sale from the inter-power sale meter communication unit 230 of the facility meter 200 (S109), and notifies the user (S110).

FIG. 6 is a flowchart showing an operation related to power sale of the facility meter 200.
First, when the ID of the power sale meter 100 is acquired from the facility meter communication unit 130 of the power sale meter 100 (S201: YES), the power sale meter communication unit 230 outputs the acquired ID to the authentication unit 240. And then. The authentication unit 240 authenticates the start of power sale through the power sale meter 100 using the ID (S202).

Subsequently, the inter-power sale meter communication unit 230 notifies the inter-facility meter communication unit 130 of the power sale meter 100 of permission or non-permission of power sale as an authentication result of step S202 (S203).
Subsequently, in the authentication result of step S202, when the power sale start is not permitted (S204: NO), the facility meter 200 finishes the process related to power sale.

On the other hand, if the result of the authentication in step S202 indicates permission to start power sale (S204: YES), power sale is started by the power sale meter 100. When the power sale ends, the power sale meter communication unit 230 acquires the measurement result of the power sale power amount from the facility meter communication unit 130 of the power sale meter 100, and the measurement result is stored in the storage unit 270. (S205).
Subsequently, the verification unit 250 verifies whether or not the measurement result of the power sale power amount acquired in S205 is reliable (S206). A specific verification method will be described later with reference to FIG.

Subsequently, if the verification result in step S206 is affirmative (S207: YES), the inter-network communication unit 260 notifies the server 300 of the measurement result of the power sale power amount as a power sale report via the network 60. (S208). Through the processing in step S208, the server 300 can grasp power sale through the power sale meter 100.
Subsequently, the power sale meter communication unit 230 notifies the facility meter communication unit 130 of the power sale meter 100 of the establishment of power sale (S209).

  On the other hand, if the verification result in step S205 is negative (S207: NO), the inter-network communication unit 260 indicates that the power sale meter 100 has a risk of, for example, malfunction or fraud via the network 60. 300 is notified (S210). Through the processing in step S210, the server 300 can grasp the state of the power sale meter 100 managed by an individual, for example, a state where there is a risk of malfunction or fraud.

Subsequently, the power sale meter communication unit 230 notifies the facility meter communication unit 130 of the power sale meter 100 that power sale is not established (S211).
Here, a verification method by the verification unit 250 will be described.
As described in the above <Background to Invention>, the facility load group 40 is provided downstream of the distribution board 20 of the facility, so that the power output from the power supply device 11 is consumed by the facility load group 40. It is assumed that Therefore, the power output from the power supply device 11 is [1] not consumed in the facility load group 40 but is reversely flowed to the distribution network of the commercial power source. [2] A part is consumed in the facility load group 40 and consumed. The surplus that has not been made flows back into the distribution network of the commercial power source. [3] All the power is consumed by the facility load group 40, and the power consumption of the facility load group 40 is covered by the power output from the power supply device 11. [ 4] The power consumed by the facility load group 40 and output from the power supply device 11 does not cover the power consumption of the facility load group 40, and the facility load group 40 is supplied with power from a commercial power source. The case of [4] is assumed. The verification unit 250 verifies whether or not the measurement result of the power sale power amount is reliable, assuming the cases [1] to [4].

FIG. 7 is a flowchart showing the verification processing operation of the verification unit 250.
When the verification unit 250 obtains the measurement result of the power sale amount by the power sale meter 100 from the power sale meter communication unit 230, the verification unit 250 refers to the storage unit 270 for the power consumption amount of the facility load group 40 in the power sale time zone. The estimation is performed using the history of the measurement result of the received power amount measurement unit 210 (S301). Here, the power consumption amount of the facility load group 40 is estimated from, for example, the transition of the received power amount that is constantly measured in step S0.

Subsequently, with reference to the storage unit 270, when the reverse power flow amount is measured in the power sale time zone (S302: YES), the reverse power flow amount (P _A ) in the power sale time zone, and in step S301 The sum (P _A + P _B ) of the estimated power consumption (P _B ) of the facility load group 40 is compared with the measured value (P _C ) of the power sales by the power sales meter 100 (S303). If the difference between the sum (P _A + P _B ) and the measured value (P _C ) of the amount of power sold by the power sale meter 100 is within a predetermined range (S304: YES), the power sale by the power sale meter 100 is performed. It is determined that the measured value of the power is reliable (S305), and if it is not within the predetermined range (S304: NO), it is determined that the measured value of the power sold by the power meter 100 is not reliable (S306).

On the other hand, in step S302, when the reverse power flow amount is not measured in the power sale time zone (S302: NO), the process proceeds to step S307.
In step S307, the verification unit 250 refers to the storage unit 270, and when the received power amount is measured in the power selling time zone (S307: YES), the estimated power consumption amount of the facility load group 40 in step S301. and (P _B), the measured value of the received power amount of the power sale time zone as the difference between _{(P D) (P B -P} D), the measured value of DENDEN force sale by power sale meter 100 and (P _C) Compare (S308). If the difference between the difference (P _B -P _D ) and the measured value (P _C ) of the amount of electric power sold by the power sale meter 100 is within a predetermined range (S309: YES), the sale by the power sale meter 100 is performed. It is determined that the measured value of the electric energy is reliable (S305), and if it is not within the predetermined range (S309: NO), it is determined that the measured value of the electric power sold by the power selling meter 100 is not reliable (S306).

On the other hand, if the received power amount is not measured in the power selling time zone in step S307 (S307: NO), the estimated power consumption amount (P _B ) of the facility load group 40 in step S301 and the power selling meter The measured value (P _C ) of the amount of electric power sold by 100 is compared (S310). If the difference between the estimated value (P _B ) of the power consumption amount of the facility load group 40 in step S301 and the measured value (P _C ) of the power sale amount by the power sale meter 100 is within a predetermined range (S311). : YES), it is judged that the measured value of the amount of electric power sold by the electric power sale meter 100 is reliable (S305). If it is not within the predetermined range (S311: NO), the measured value of the electric energy sold by the electric power sale meter 100 is It is determined that it is not reliable (S306).

In addition, what is necessary is just to set the predetermined range in the process of step S304, S309, and S311 according to the power loss degree in the process of a power distribution, respectively, for example. Further, in the processes of steps S304, S309, and S311, the reliability of the power sale power amount is verified using the difference, but a ratio may be used instead of the difference.
As described above, according to the power sale system 1 of the first embodiment, the power sale meter 100 provided between the power supply device 11 and the outlet 50 converts the power amount output from the power supply device 11 into the power sale power amount. It becomes possible to measure as. In addition, authentication of the start of power sale through the power sale meter 100 can be performed by the facility meter 200 having a communication function with the server 300. Further, the facility meter 200 verifies whether or not the measurement result of the power sale power amount by the power sale meter 100 is reliable. If the verification result is negative, the power sale meter is determined to be unsuccessful. It becomes possible to suppress falsification of the value.

<1-3. Modification 1>
In the power selling system 1 of the first embodiment, the communication unit is provided between the power selling meter 100 and the facility meter 200. On the other hand, in the first modification, the mobile terminal mediates communication between the power sale meter and the facility meter.
Hereinafter, the power selling system according to the first modification will be described with reference to the drawings. In the power selling system according to the first modification, components that perform substantially the same processing as the power selling system 1 according to the first embodiment are denoted by the same reference numerals, and description thereof is omitted.

FIG. 8 is a configuration diagram of a power selling system 1A of the first modification.
The power sale system 1A is the same as the power sale system 1 of the first embodiment except that the portable terminal 70 is added, the power sale meter 100 is replaced with the power sale meter 100A, and the facility meter 200 is replaced with the facility meter 200A. .
The power sale meter 100A is obtained by replacing the facility meter communication unit 130 with a portable terminal communication unit 130A in the power sale meter 100. The inter-mobile terminal communication unit 130 </ b> A communicates with the mobile terminal 70, and communicates with the facility meter 200 </ b> A via the mobile terminal 70.

The facility meter 200A is obtained by replacing the power meter communication unit 230 with a portable terminal communication unit 230A in the facility meter 200. The portable terminal communication unit 230 </ b> A communicates with the portable terminal 70 and communicates with the power sale meter 100 </ b> A via the portable terminal 70.
The portable terminal 70 communicates with the portable terminal communication unit 130A of the power sale meter 100A and the portable terminal communication unit 230A of the facility meter 200A, respectively, and exchanges data between the power sale meter 100A and the facility meter 200A. Mediate.

Note that, for example, proximity wireless communication may be used as a communication unit between the mobile terminal communication unit 130A and the mobile terminal 70. Since the portable terminal 70 mediates communication between the power sale meter 100A and the facility meter 200A, the configuration related to the communication of the power sale meter 100A can be simplified.
In the power sale system 1 of the first embodiment, the power sale meter 100 notifies the facility meter 200 of the ID of the power sale meter 100, and the facility meter 200 notifies the ID of the notified power sale meter 100. Based on the above, it was decided to authenticate the start of power sales. On the other hand, in the power sale system 1A of this modification, since the mobile terminal 70 mediates between the power sale meter 100A and the facility meter 200A, the mobile terminal 70 notifies the facility meter 200A of the ID of the mobile terminal 70, The facility meter 200A may authenticate the start of power sale based on the notified ID of the portable terminal 70. In this case, the server 300 uses the ID of the mobile terminal 70 and the ID of the user who owns the mobile terminal 70 (the power selling user who sells power through the mobile terminal) as the registration information of the mobile terminal 70 in advance. You should keep it.

<1-4. Modification 2>
In the power sale system 1 of the first embodiment, when the facility meter 200 inquires of the server 300 whether the ID acquired from the power sale meter 100 is registered and authenticates the start of power sale. did. On the other hand, in the second modification, it is assumed that the server authenticates the start of power sale. As a result, for example, when the power supply of the commercial power supply system is not short and power selling is unnecessary, it is possible to perform a restriction that the administrator does not sell power.

Hereinafter, the power selling system of Modification 2 will be described with reference to the drawings. In the power selling system according to the second modification, the same reference numerals are given to components that perform substantially the same processing as the power selling system 1 according to the first embodiment, and the description thereof is omitted.
FIG. 9 is a configuration diagram of a power selling system 1B according to the second modification.
The power sale system 1B is obtained by replacing the facility meter 200 with the facility meter 200B and replacing the server 300 with the server 400 in the power sale system 1 of the first embodiment.

The facility meter 200B is obtained by replacing the inter-network communication unit 260 with an inter-network communication unit 260B in the facility meter 200, except for the authentication unit 240.
The inter-network communication unit 260B has a function of communicating with the server 400 via the network 60.
Specifically, the inter-network communication unit 260 </ b> B notifies the server 400 of the verification result of the verification unit 250 and the measurement result of the electric power sales amount stored in the storage unit 270. These functions and operations are the same as those performed on the server 300 by the inter-network communication unit 260 of the first embodiment.

Furthermore, the inter-network communication unit 260B notifies the server 400 of the ID of the power sale meter 100 acquired by the power sale meter-to-meter communication unit 230, and requests authentication of the start of power sale via the power sale meter 100. And the authentication result of the power sale start is acquired from the server 400, and the authentication result is output to the communication unit 230 between power sale meters.
The server 400 is a server device that manages power sale through the power sale meter 100, and includes a user information storage unit 410, a communication unit 420, and an authentication unit 430.

The user information storage unit 410 has a function of storing registration information of the power sale meter 100. The registration information of the power sale meter 100 is as described in the first embodiment.
The communication unit 420 has a function of communicating with the facility meter 200B via the network 60.
Specifically, the communication unit 420 acquires a notification of a power sale report via the power sale meter 100. The function of the communication unit 420 is the same as the communication function described in the server 300 of the first embodiment. In addition, the communication unit 420 obtains the ID of the power sale meter 100 from the facility meter 200B, and notifies the authentication result of the start of power sale via the power sale meter 100 by the authentication unit 430.

The authentication unit 430 receives an instruction to limit power sale from the manager of the commercial power supply, and starts selling power via the power sale meter 100 based on the instruction and the ID of the power sale meter 100 acquired from the facility meter. It has a function to authenticate whether or not to accept.
Specifically, when the ID of the power sale meter 100 is acquired from the facility meter 200B, for example, when an instruction for not permitting the start of power sale is received in advance from the manager of the commercial power supply, the power sale start is started. Is not allowed.

  On the other hand, when such an instruction for disabling the start of power sale is not received, the user information storage unit 410 is referred to and it is confirmed whether or not the power sale meter 100 with the ID is registered. And if the power sale meter 100 of the ID is registered, the start of power sale is permitted, and if the power sale meter 100 of the ID is not registered, the start of power sale is not permitted. The manager of the commercial power system, for example, disallows the start of power sale via the outlet when there is sufficient power in the power supply state of the commercial power system and power sale via the outlet is not required. An instruction may be given to the authentication unit 430.

As described above, according to the power selling system 1B of the second modification, the manager of the commercial power supply system can limit the power selling through the power selling meter 100.
In addition, the instruction by the manager of the commercial power supply system is not limited to an instruction that does not permit the start of power sale, but may be an instruction that limits the amount of power sold. In this case, when the registration of the power sale meter with the ID is confirmed, the facility meter 200B is notified of the amount of power permitted to sell power via the communication unit 420, and sold via the facility meter 200B and the power sale meter 100. You may make it output to a power supply device only the electric energy which accept | permits electricity.

Further, in the second modification, the example in which the server 400 restricts power sale in accordance with an instruction from the administrator has been described, but the ID of the power sale meter 100 is similar to the authentication by the facility meter 200 according to the first embodiment. It may be possible to authenticate the start of power sale by checking only whether or not is registered.
<1-5. Modification 3>
In the first embodiment, the inter-network communication unit 260 of the facility meter 200, if the verification result in step S205 (FIG. 6) is negative (S207: NO), the power sale meter 100 via the network 60. For example, it has been explained that the server 300 is notified that there is a risk of malfunction or fraud (S210). Through the processing in step S210, the server 300 can grasp the state of the power sale meter 100 managed by an individual, for example, a state where there is a risk of malfunction or fraud.

Therefore, for example, if the server is notified that there is a risk of malfunction or fraud in the power sale meter, for example, the server adds the power sale meter to the blacklist and disallows power sale via the power sale meter. You may manage so that.
<< 2-1. Second Embodiment >>
In the power selling system 1 of the first embodiment, the power selling meter 100 notifies the facility meter 200 of the measurement result after measuring the amount of power sold, and the facility meter 200 verifies the notified measurement result to establish the power sale. Or it was decided that it was not established. On the other hand, in the power sale system of the second embodiment, before the power sale meter starts selling power, the power amount output from the power supply device is measured experimentally, and the experimental measurement result is used as a facility meter. Notice. Then, the facility meter verifies the notified experimental measurement result, and determines whether to start or sell power.

Hereinafter, the power selling system of the second embodiment will be described with reference to the drawings. In the power selling system of the second embodiment, the same reference numerals are given to components and processing steps that perform substantially the same processes as those of the power selling system 1 of the first embodiment, and a description thereof is omitted.
<2-1-1. Configuration>
FIG. 10 is a configuration diagram of the power selling system 2 according to the second embodiment.

The power sale system 2 is obtained by replacing the power sale meter 100 with the power sale meter 500 and replacing the facility meter 200 with the facility meter 600 in the power sale system 1 of the first embodiment.
The power sale meter 500 is obtained by replacing the control unit 140 with the control unit 510 in the power sale meter 100 of the first embodiment.

Similar to control unit 140 of the first embodiment, control unit 510 controls on / off of the power output of power supply device 11 according to the authentication result of the start of power sale output from inter-facility meter communication unit 130. It has a function.
Then, the control unit 510 further acquires a notification of the test measurement power amount from the facility meter 600 via the facility meter communication unit 130, and causes the power supply device 11 to output power by the test measurement power amount. It has a function to perform.

The facility meter 600 is obtained by adding an authentication verification unit 610 to the facility meter 200 of the first embodiment except for the authentication unit 240 and the verification unit 250.
The authentication verification unit 610 has a function of authenticating the start of power sale via the power sale meter 500. Details of the processing of the authentication verification unit 610 are described in <2-1-2. Operation> will be described later.
<2-1-2. Operation>
FIG. 11 is a sequence diagram illustrating the overall operation of the power sale system 2.

The facility meter 600 constantly measures and stores the amount of received power and the amount of reverse power flow (S0). The measurement results of the received power amount and the reverse flow power amount are used in the verification process (S26) in the authentication verification unit 610.
First, when the power sale meter 500 receives a request for starting power sale from the power supply device 11, the power sale meter 500 notifies the facility meter 600 of the ID of its own device (S1).

  In response to this, the facility meter 600 performs registration confirmation as to whether or not the power sale meter 500 is registered in the server 300 using the ID of the power sale meter 500 notified in step S1 (S21). If the registration is not confirmed in step S <b> 21, the facility meter 600 determines that the power sale via the power sale meter 500 is not permitted and notifies the power sale meter 500 to that effect. On the other hand, if the registration is confirmed in step S21, a power amount for test measurement for causing the power sale meter 500 to perform test measurement is notified (S22).

  In response to this, the power sale meter 500 causes the power supply device 11 to output power for the test measurement power amount notified in step S22 (S23). And the electric energy output from the power supply device 11 is measured experimentally and memorize | stored (S24). When the power output from the power supply device 11 is finished, the facility meter 600 is notified of the result of the test measurement in step S24 (S25).

In response, the facility meter 600 verifies whether or not the result of the test measurement notified in step S25 is reliable (S26). If the result of the test measurement is reliable in step S26, the power sale meter 500 is notified of permission to start power sale. If the result of the test measurement is not reliable, the power sale meter 500 is notified of permission to start power sale. (S3).
Upon receiving the notification permitting power sale in step S27, the power sale meter 500 causes the power supply device 11 to output power (S4). And the electric energy output from the power supply device 11 is measured and memorize | stored (S5). And if the electric power output from the power supply device 11 is complete | finished, the measurement result of step S5 will be notified to the facility meter 600 (S6).

In response to this, the facility meter 600 notifies the server 300 of the measurement result of the electricity sales watt-hour meter as a report of power sale (S27). Then, the power sale meter 500 is notified of the establishment of power sale (S28).
In response, the power sale meter 500 notifies the user of the establishment of power sale (S29).

Next, specific operations of the power sale meter 500 and the facility meter 600 will be described.
FIG. 12 is a flowchart showing the operation of the power sale meter 500.
First, when the power sale meter 500 receives a power sale start request from the power supply device 11, the facility meter communication unit 130 notifies the power meter communication unit 230 of the facility meter 600 of the ID of its own device (S101). ).

Subsequently, when the inter-facility meter communication unit 130 receives a power sale start disapproval notification from the inter-power sale meter communication unit 230 of the facility meter 600 (S401: YES), the notification is output to the control unit 510. The control unit 510 notifies the user that the start of power sale is not permitted and ends the process (S104).
On the other hand, when the notification of the power consumption for test measurement is received from the communication unit 230 between the power sale meters of the facility meter 600 as a test measurement instruction without receiving a notification of permission to start selling power (S401: NO) (S402: YES), the notification is output to the control unit 510. The control unit 510 causes the power supply device 11 to output power by the test measurement power amount (S403).

When power is output from the power supply device 11 in step S403, the power sale power amount measurement unit 110 measures the power amount output from the power supply device 11 on a trial basis and stores it in the power sale power amount storage unit 120 (S404). . Until the output for the test measurement by the power supply device 11 is completed, the process of step S106 is repeated (S405: NO).
When the power output for test measurement by the power supply device 11 is completed (S405: YES), the facility meter communication unit 130 performs the test measurement in step S404 on the power sale meter communication unit 230 of the facility meter 600. The result is notified (S406).

In the notification in step S406, the date and time of measurement and the amount of power may be notified as a test measurement result, or notification that the output power for test measurement (P _TEST ) has been correctly measured is sent. May be.
After step S406, the facility meter 600 verifies whether or not the result of the experimental measurement notified in step S406 is reliable, and determines whether or not to start power sale depending on the verification result. . Then, the inter-facility meter communication unit 130 obtains a report notification of permission or non-permission of power sale from the inter-power sale meter communication unit 230 of the facility meter 600 and outputs it to the control unit 510 (S407). If start of power sale is not permitted (S408: NO), control unit 510 informs the user that start of power sale is not permitted and ends the process (S104).

  On the other hand, if the start of power sale is permitted (S408: YES), power is output to the power supply device 11 (S105), and the power sale power amount measurement unit 110 measures the power sale power amount and stores it in the power sale power amount storage unit 120. When the power output by the power supply device 11 is completed (S107: YES), the inter-facility meter communication unit 130 determines the amount of power sold in step S106 to the inter-meter sales communication unit 230 of the facility meter 600. The measurement result is notified (S108).

Subsequently, the inter-facility meter communication unit 130 acquires a report of establishment of power sale from the inter-power sale meter communication unit 230 of the facility meter 600 (S409), and notifies the user (S410).
FIG. 13 is a flowchart showing an operation related to power sale of the facility meter 600.
First, when the power sale meter communication unit 230 acquires the ID of the power sale meter 500 from the facility meter communication unit 130 of the power sale meter 500 (S201: YES), the power sale meter communication unit 230 outputs the acquired ID to the authentication verification unit 610. Then, the authentication verification unit 610 checks whether or not the power sale meter 500 corresponding to the ID is registered in the server 300 (S501).

Specifically, the server 300 is inquired via the inter-network communication unit 260 and the network 60. Then, an inquiry response is obtained from the server, and registration is confirmed.
Subsequently, in step S501, if the power sale meter 500 corresponding to the ID is not registered (S502: NO), the authentication verification unit 610 does not permit the start of power sale via the power sale meter 500 (S503). ). Then, the power sale meter communication unit 230 notifies the facility meter communication unit 130 of the power sale meter 500 that the start of power sale is not permitted (S504).

On the other hand, if the power sale meter 500 corresponding to the ID is registered in step S501 (S502: YES), the authentication verification unit 610 uses the facility meter of the power sale meter 500 via the power sale meter communication unit 230. The inter-communication unit 130 is notified of the test power amount (S505).
After step S505, measurement of a trial electric energy is started on the power sale meter 500 side, and when the measurement ends, the power sale meter communication unit 230 performs a test from the facility meter communication unit 130 of the power sale meter 500. A measurement result of the amount of electric power is acquired and output to the authentication verification unit 610 (S506).

Subsequently, the authentication verification unit 610 verifies whether or not the output measurement result of the experimental electric energy is reliable (S507). This verification processing is performed using a method similar to the method described with reference to FIG. 7 in the first embodiment.
If the verification result in step S507 is negative (S508: NO), the authentication verification unit 610 determines not to permit power sale start (S509). Subsequently, the inter-network communication unit 260 notifies the server 300 that there is a possibility that the power sale meter 500 is defective via the network 60 (S510). Subsequently, the power sale meter communication unit 230 notifies the facility meter communication unit 130 of the power sale meter 500 that the start of power sale is not permitted (S504).

On the other hand, if the verification result in step S507 is affirmative (S508: YES), the authentication verification unit 610 determines to permit the start of power sale (S511). Subsequently, the power sale meter communication unit 230 notifies the facility meter communication unit 130 of the power sale meter 500 that permission to start power sale is permitted (S512).
After step S512, power sale is started by the power sale meter 500, and when the power sale is completed, the power sale meter communication unit 230 receives the measurement result of the power sale power amount from the facility meter communication unit 130 of the power sale meter 500. The measurement result is acquired and stored in the storage unit 270 (S513).

Subsequently, the inter-network communication unit 260 notifies the server 300 of the measurement result of the power sale power amount as a power sale report via the network 60 (S514).
Next, the power sale meter communication unit 230 notifies the facility meter communication unit 130 of the power sale meter 500 that power sale has been established (S515).
As described above, according to the power sale system 2 of the first embodiment, after confirming the reliability of the measurement of the amount of power sold by the power sale meter 500, the power is output to the outlet and the power sale is started. Is possible.

<< 2-2. Embodiment 2A >>
In the power selling system 2 of the second embodiment, before the power selling meter 500 starts to sell power, the power amount output from the power supply device is experimentally measured, and the measurement result is verified by the facility meter 600. It was decided to decide whether to start or sell electricity. On the other hand, in the power sale system of the present embodiment 2A, the power sale meter measures the amount of power output from the power supply device to the outlet and measures the amount of power input from the outlet to the power sale meter. (Bidirectional energy measurement function) is provided. Further, the power sale meter is provided with a function of consuming power by itself, the amount of power consumed by itself is measured, and the measurement result is notified to the facility meter. The facility meter compares the transition of the amount of power received by the facility from the commercial power supply with the measurement result of the power consumption of the power sale meter notified by the power sale meter. The reliability of the power supply is verified, and permission or disapproval of the start of power sale is determined.

Hereinafter, the power selling system of Embodiment 2A will be described with reference to the drawings. In the power selling system of Embodiment 2A, components and processing steps that perform substantially the same processing as the power selling systems of the above-described embodiments are assigned the same reference numerals, and descriptions thereof are omitted.
<2-2-1. Configuration>
FIG. 14 is a configuration diagram of the power sale system 2A of the present embodiment 2A.

The power selling system 2A is obtained by replacing the power selling meter 100 with the power selling meter 1500 and replacing the facility meter 200 with the facility meter 1600 in the power selling system 1 of the first embodiment.
The power sale meter 1500 is the same as the power sale meter 100 of the first embodiment except that a switching unit 1510, a power consumption unit 1530, and a power consumption measurement unit 1540 are added, and the control unit 140 is replaced with a control unit 1520. The electric energy storage unit 120 is replaced with a storage unit 1550.

Further, the inter-facility meter communication unit 130 of the embodiment 2A acquires a power consumption instruction for consuming power for a predetermined time for test measurement from the power sale inter-meter communication unit of the facility meter 1600.
The switching unit 1510 switches between the connection between the control unit 1520 and the power supply terminal 160 and the connection between the control unit 1520 and the power consumption unit 1530 in accordance with an instruction from the facility meter 1600 via the facility meter communication unit 130. Has a function to perform operations.

  Specifically, when an instruction for power consumption from the facility meter 1600 is acquired, an operation of switching so that the control unit 1520 and the power consumption unit 1530 are connected is performed. Control unit 1520 and power consumption unit 1530 are connected only when an instruction for power consumption from facility meter 1600 is acquired, and otherwise control unit 1520 and power supply terminal 160 are connected. Also good.

Similarly to the control unit 140 of the first embodiment, the control unit 1520 controls on / off of the power output of the power supply device 11 according to the authentication result of the start of power sale output from the inter-facility meter communication unit 130. It has a function.
The control unit 1520 further has a function of performing on / off control of the power consumption of the power consumption unit 1530 according to the power consumption instruction acquired from the facility meter 1600 to consume power for a predetermined time for the test measurement. Have. Specifically, the power consumption unit 1530 consumes power for the predetermined time by the on control.

When the power consumption unit 1530 is connected to the control unit 1520 by the switching unit 1510, the power consumption unit 1530 has a function of consuming power according to the control of the control unit 1520.
The power consumption measuring unit 1540 has a function of measuring the power consumption of the power consumption unit 1530, in other words, the amount of power output from the outlet 50 to the power sale meter 1500.
Note that the power consumption measuring unit 1540 and the power sale power measuring unit 110 may be mounted as one configuration for measuring bidirectional power.

The storage unit 1550 has a function of storing the power sale power amount measurement result output from the power sale power amount measurement unit 110 in the same manner as the power sale power amount measurement unit 120 of the first embodiment. Further, the storage unit 1550 has a function of storing the measurement result of the power consumption amount of the power consumption unit 1530 output from the power consumption amount measurement unit 1540.
The facility meter 1600 is the same as the facility meter 200 of the first embodiment except that the reverse flow power amount measurement unit 220, the authentication unit 240, and the verification unit 250 are added, and an authentication verification unit 1610 is added, and the storage unit 270 is stored in the storage unit 270. It is replaced with 1620.

The authentication verification unit 1610 has a function of authenticating the start of power sale via the power sale meter 1500. Details of the processing of the authentication verification unit 1610 are described in <2-2-2. Operation> will be described later.
The storage unit 1620 has a function of storing the measurement result of the received power amount measurement unit 210 and the measurement result of the power sale power amount acquired by the inter-power sale meter communication unit 230.
<2-2-2. Operation>
FIG. 15 is a sequence diagram showing the overall operation of the power sale system 2A.

The facility meter 1600 constantly measures and stores the amount of received power (S0A). The measurement result of the received power amount is used in the verification process (S125) in the authentication verification unit 1610.
First, when the power sale meter 1500 receives a power sale start request from the power supply device 11, the power sale meter 1500 notifies the facility meter 1600 of the ID of its own device (S1).
In response to this, the facility meter 1600 uses the ID of the power sale meter 1500 notified in step S1 to confirm registration of whether or not the power sale meter 1500 is registered in the server 300 (S21). If registration is not confirmed in step S <b> 21, the facility meter 1600 does not accept power sale via the power sale meter 1500 and notifies the power sale meter 1500 to that effect. On the other hand, if the registration is confirmed in step S21, the power sale meter 1500 is instructed to consume power for a predetermined time in order to perform test measurement (S121).

In response, the power sale meter 1500 consumes power for a predetermined time (S122). Then, the power consumption, in other words, the power input from the outlet to the power sale meter 1500 is measured and stored (S123). When the power consumption for a predetermined time is finished, the facility meter 1600 is notified of the measurement result of the power consumption in step S123 (S124).
In response to this, the facility meter 1600 verifies whether or not the measurement result notified in step S124 is reliable (S125). If the measurement result is reliable in step S125, the power sale meter 1500 is notified of permission to start power sale, and if the measurement result is not reliable, the power sale meter 1500 is notified of permission to start power sale (S3). .

Subsequent steps S4 to S6 and S27 to S29 are the same as the entire operation (FIG. 11) of the power selling system 2 of the second embodiment.
Next, specific operations of the power sale meter 1500 and the facility meter 1600 will be described.
FIG. 16 is a flowchart showing the operation of the power sale meter 1500.

The operation of the power sale meter 1500 shown in FIG. 16 is obtained by replacing steps S402 to S406 with steps S421 to S425 in the operation of the power sale meter 500 of the second embodiment shown in FIG.
That is, in step S401, a notification of power consumption instruction is issued so as to consume power for a predetermined time without receiving the notification of permission to start power sale from the power sale meter communication unit 230 of the facility meter 1600 (S401: NO). When received (S421: YES), the switching unit 1510 performs an operation of connecting the control unit 1520 and the power consuming unit 1530, and the control unit 1520 performs on-control that causes the power consuming unit 1530 to consume power for a predetermined time. As a result, the power consumption unit 1530 consumes power for a predetermined time (S422).

When power is consumed in step S422, the power consumption measuring unit 1540 measures the power consumption and stores it in the storage unit 1550 (S423). The process of step S423 is repeatedly performed until a predetermined time has elapsed (S424: NO).
When a predetermined time in the power consumption instruction elapses (S424: YES), the control unit 1520 performs an off control that causes the power consumption unit 1530 to end the power consumption. And the facility meter communication part 130 notifies the measurement result of the power consumption of step S423 to the power sale meter communication part 230 of the facility meter 1600 (S425).

After step S425, the facility meter 1600 verifies whether or not the measurement result notified in step S425 is reliable, and determines whether or not to start power sale depending on the verification result.
Subsequent processing steps, that is, steps S407 to S410 and S104 to S108 are the same as the operation of the power sale meter 500 of the second embodiment (FIG. 12).

FIG. 17 is a flowchart showing the operation of the facility meter 1600.
The operation of the facility meter 1600 shown in FIG. 17 is obtained by replacing steps S505 to S508 with steps S521 to S524 in the operation of the facility meter 1600 of the second embodiment shown in FIG.
That is, if the power sale meter 500 corresponding to the ID is registered in step S501 (S502: YES), the authentication verification unit 1610 uses the facility meter of the power sale meter 1500 via the power sale meter communication unit 230. In order to perform test measurement to the inter-communication unit 130, a power consumption instruction is notified to consume power for a predetermined time (S521).

After step S521, the power sale meter 1500 consumes power for a predetermined time, and when this is completed, the power sale meter communication unit 230 receives power consumption for a predetermined time from the facility meter communication unit 130 of the power sale meter 1500. An amount measurement result is acquired and output to the authentication verification unit 1610 (S522).
Subsequently, the authentication verification unit 1610 verifies whether or not the measurement result output in step S522 is reliable (S523). A specific verification method will be described later with reference to FIG.

If the verification result in step S523 is affirmative (S524: YES), the authentication verification unit 1610 determines permission to start selling power (S511), whereas if it is negative (S524: NO), the authentication verification unit 1610 determines the disapproval of power sale start (S509).
Subsequent processing steps, that is, steps S510 to S515 are the same as the operation of the facility meter 600 of the second embodiment (FIG. 13).

Here, a verification method by the authentication verification unit 1610 will be described.
FIG. 18 is a flowchart showing the verification processing operation of the authentication verification unit 1610.
When the authentication verification unit 1610 acquires the measurement result of the power consumption by the power sale meter 1500 from the power sale meter communication unit 230, the power sale meter 1500 has not consumed power for the predetermined time indicated in step S521. The amount of received power when assumed is estimated (S321). Here, the received power amount in the case of the assumption is estimated from, for example, the transition of the received power amount that is constantly measured in step S0A.

  Subsequently, the authentication verification unit 1610 refers to the storage unit 1620 and compares the amount of received power for the predetermined time designated in step S521 with the estimation result in step S321 (S322). Then, in the comparison in step S322, when the difference between the two can be considered to be due to the power consumption of the power sale meter 1500 (S323: YES), it is determined that the measurement result of the power sale power amount by the power sale meter 1500 is reliable (S305). ). On the other hand, when it cannot be considered that it is due to the power consumption of the power sale meter 1500 (S323: NO), it is determined that the measurement result of the amount of power sold by the power sale meter 1500 is not reliable (S306).

<2-2-3. Supplement>
In Embodiment 2A, facility meter 1600 notifies a power consumption instruction to consume power for a predetermined time in order to perform test measurement. In response to the notification, the power sale meter 1500 consumes power for a predetermined time, measures the amount of power consumption, and notifies the facility meter 1600, but is not limited thereto. For example, the facility meter 1600 repeats an instruction for consuming power for a predetermined time and an instruction for not consuming power for a predetermined time in a time period during which test measurement is performed in order to cause the power sale meter 1500 to perform test measurement. (Or notify all at once). Then, the control unit 1520 may control power consumption and non-consumption by the power consumption unit 1530 according to the notification.

An example of verification of power consumption of the power sale meter 1500 by the authentication verification unit 1610 will be described with reference to FIG.
FIG. 19A shows an example of a result of estimating the received power amount when it is assumed that power is not consumed in the power sale meter 1500 in step S321, and an example of the received power amount by the received power amount measuring unit 210. FIG. 19B shows an example of the measurement result of the power consumption by the power sale meter 1500. The times in FIGS. 19A and 19B correspond to each other.

As shown in FIG. 19A, the measured value of the received power amount is increased by the amount of power consumed by the power sale meter 1500 with respect to the estimated value of the received power amount.
As shown in FIG. 19A, the authentication verification unit 1610 can consider that the increase in the measured value of the received power amount with respect to the estimated value of the received power amount is due to the power consumption by the power sale meter 1500. You may judge that the measurement result of the electric power sale amount by the electric power sale meter 1500 is reliable.

≪3. Embodiment 3 >>
In the power sale system 1 of the first embodiment, the facility meter 200 verifies the measurement result of the power sale power amount by the power sale meter 100. In the power selling system of the third embodiment, the facility meter gives a predetermined output power value to the power selling meter so that the facility meter can be easily verified, and the power selling meter supplies power to the power supply device at the predetermined output value. Is output.

Hereinafter, the power selling system of the third embodiment will be described with reference to the drawings. In the power selling system according to the third embodiment, the same reference numerals are given to components and processing steps that perform substantially the same processing as the power selling system according to each of the above embodiments, and the description thereof is omitted.
<3-1. Configuration>
FIG. 20 is a configuration diagram of the power selling system 3 according to the third embodiment.

The power selling system 3 is obtained by replacing the power selling meter 100 with the power selling meter 700 and replacing the facility meter 200 with the facility meter 800 in the power selling system 1 of the first embodiment.
The power sale meter 700 is obtained by replacing the control unit 140 with a control unit 710 in the power sale meter 100 of the first embodiment.

Similarly to the control unit 140 of the first embodiment, the control unit 710 controls on / off of the power output of the power supply device 11 according to the authentication result of the start of power sale output from the inter-facility meter communication unit 130. It has a function.
Then, the control unit 710 further acquires a notification of the output power value from the facility meter 800 via the facility meter communication unit 130, controls the power supply device 11 to be turned on, and supplies the power supply device 11 with the acquired output power value. It has a function of performing control to output electric power.

In the facility meter 800, an output control unit 810 is further added to the facility meter 200 of the first embodiment, and the verification unit 250 is replaced with a verification unit 820.
The output control unit 810 has a function of notifying the power sale meter 700 of a predetermined output power value via the power sale meter communication unit 230 and controlling the output power value of the power supply device 11.
The verification unit 820 has a function of verifying whether or not the measurement result of the power sale power amount obtained by the power sale meter 700 acquired by the power sale meter communication unit 230 is reliable. Details of the verification method are described in <3-2. Operation> will be described later.

<3-2. Operation>
FIG. 21 is a sequence diagram showing the overall operation of the power sale system 1.
The facility meter 800 constantly measures and stores the amount of received power and the amount of reverse power flow (S0). Note that the measurement results of the received power amount and the reverse power flow energy amount are used in the verification process (S33) in the verification unit 820.

First, when the power sale meter 700 receives a power sale start request from the power supply device 11, the power sale meter 700 notifies the facility meter 800 of the ID of its own device (S1).
In response to this, the facility meter 800 uses the ID of the power sale meter 700 notified in step S1 to confirm registration of whether or not the power sale meter 700 is registered in the server (S21). If the registration is not confirmed in step S <b> 21, the facility meter 800 notifies the power sale meter 700 that the power sale via the power sale meter 700 is not permitted. On the other hand, if the registration is confirmed in step S21, the power sale meter 700 is notified of a predetermined output power value in order to control the output power value to the outlet (S31).

When receiving the notification of the predetermined output power value in step S22, the power sale meter 700 causes the power supply device 11 to output power at the output power value (S32).
Subsequently, the power sale meter 700 measures the amount of power sold (S5), and notifies the facility meter 800 of the measurement result (S6).
In response to this, the facility meter 800 verifies whether or not the measurement result of the power sale power amount notified in step S6 is reliable (S33). This verification method is different from that of the first embodiment. Details will be described later with reference to FIG.

Subsequently, the facility meter 800 reports power sale to the server 300 according to the verification result of step S33 (S8), and then notifies the power sale meter 700 of establishment or non-establishment of power sale (S9).
In response, the power sale meter 700 notifies the user of the establishment or non-establishment of power sale (S10).

Next, specific operations of the power sale meter 700 and the facility meter 800 will be described.
FIG. 22 is a flowchart showing the operation of the power sale meter 700.
First, when the power sale meter 700 receives a power sale start request from the power supply device 11, the facility meter communication unit 130 notifies the power meter communication unit 230 of the facility meter 800 of the ID of its own device (S101). ).

Subsequently, when the facility meter communication unit 130 receives a notification of the start of power sale from the power sale meter communication unit 230 of the facility meter 800 (S401: YES), the notification is output to the control unit 710. The control unit 710 informs the user that the start of power sale is not permitted and ends the process (S104).
On the other hand, if the notification of the start of power sale is not received from the communication unit 230 between the power sale meters of the facility meter 800 (S301: NO), if a notification of a predetermined power output amount value is received (S601: YES), then The notification is output to the control unit 710, and the control unit 710 causes the power supply device 11 to output power at a predetermined output power value (S602).

Subsequently, the power sale power amount measurement unit 110 measures the power sale power amount and stores it in the power sale power amount storage unit 120 (S106). When the power output by the power supply device 11 is completed (S107: YES), the inter-facility meter communication unit 130 notifies the measurement result of the amount of power sold in step S106 to the power sale meter communication unit 230 of the facility meter 800 (S108).
In response to this, the facility meter 800 verifies whether or not the measurement result of the power sale power amount notified in step S108 is reliable, and determines whether the power sale is established or not according to the verification result. Then, the inter-facility meter communication unit 130 obtains a notification of establishment or non-establishment of power sale from the inter-power sale meter communication unit 230 of the facility meter 800 (S109) and notifies the user (S110).

FIG. 23 is a flowchart showing an operation related to power sale of the facility meter 800.
In FIG. 23, the processing in steps S501A to S504A performed by the authentication unit 240 and the power sale meter communication unit 230 of the facility meter 800 is the same as the authentication verification unit 610 and the power sale of the facility meter 600 of the second embodiment. This is the same as the processing in steps S501 to S504 performed by the inter-meter communication unit 230.

That is, first, when the power sale meter communication unit 230 obtains the ID of the power sale meter 700 from the facility meter communication unit 130 of the power sale meter 700 (S201: YES), it outputs the obtained ID to the authentication unit 240. . And the authentication part 240 confirms whether the power sale meter 700 corresponding to the ID is registered into the server 300 (S501A).
Subsequently, in step S501A, if the power sale meter 700 corresponding to the ID is not registered (S502A: NO), the authentication unit 240 determines that the start of power sale via the power sale meter 700 is not permitted (S503A). ), The power sale meter communication unit 230 notifies the facility meter communication unit 130 of the power sale meter 700 to that effect (S504A).

On the other hand, if the power sale meter 700 corresponding to the ID is registered in step S501A (S502A: YES), the output control unit 810 uses the facility meter of the power sale meter 700 via the power sale meter communication unit 230. A predetermined output power value is notified to the inter-communication unit 130 (S701).
After step S701, the power sale meter 700 performs power output control with the predetermined output power value notified in step S701, and measures the amount of power sold. When the power output is completed, the power sale meter communication unit 230 acquires the measurement result of the power sale power amount from the facility meter communication unit 130 of the power sale meter 700, and the measurement result is stored in the storage unit 270. (S205).

Subsequently, the verification unit 820 verifies whether or not the measurement result of the power sale power amount acquired in step S205 is reliable (S702).
Here, a verification method by the verification unit 820 will be described.
In the present embodiment, the facility meter 800 notifies the power sale meter 700 of a predetermined output power value, and the power sale meter 700 performs output control to output power to the power supply device 11 at the predetermined power value. . Therefore, since the output power amount value from the power supply device 11 is determined, the verification unit 820 easily estimates the power sale power amount by estimating the time zone (power sale time zone) when the power supply device 11 outputs power. It becomes possible.

FIG. 24 is a flowchart showing the verification processing operation of the verification unit 820.
When the verification unit 820 acquires the measurement result of the power sale power amount by the power sale meter 700 from the power sale meter communication unit 230, the verification unit 820 refers to the storage unit and measures the measurement result of the received power amount measurement unit 210 and the reverse power flow energy measurement. The power sale time zone is estimated using the measurement result of the unit 220 (S801). In step S801, the verification unit 820 displays, for example, the time zone immediately after the authentication of the start of power sale, the time zone in which the reverse power flow amount is measured, or the time zone in which the received power amount is reduced. Estimated.

Subsequently, the verification unit 820 estimates the power sale power amount by multiplying the power sale time period estimated in step S801 by the output power value notified to the power sale meter 700 in step S701 (S802).
Subsequently, the power sale power amount measured by the power sale meter 700 and acquired from the power sale meter communication unit 230 is compared with the power sale power amount estimated in Step S802. If the difference is within a predetermined range (S803: YES), it is determined that the measurement result of the amount of power sold by the power sale meter 700 is reliable (S305), and the difference is not within the predetermined range (S305). S803: NO), it is determined that the measurement result of the amount of power sold by the power sale meter 700 is not reliable (S306).

Returning to FIG. 23, the description will be continued.
If the verification result in step S702 is affirmative (S207: YES), the inter-network communication unit 260 notifies the server 300 of the measurement result of the power sale power amount as a power sale report (S208). Next, the power sale meter communication unit 230 notifies the facility meter communication unit 130 of the power sale meter 700 that the power sale has been established (S209).

On the other hand, if the verification result in step S702 is negative (S207: NO), the inter-network communication unit 260 notifies the server 300 that there is a possibility that the power sale meter is defective (S210). Subsequently, the power sale meter communication unit 230 notifies the facility meter communication unit 130 of the power sale meter 700 that power sale is not established (S211).
As described above, according to the power sale system 3 of the third embodiment, the facility meter 800 gives a predetermined output power value to the power sale meter 700 so that the power sale meter 700 can measure the amount of power sold. Reliability can be easily verified.

<3-3. Modification>
As described above, in the present embodiment, the facility meter 800 gives a predetermined output power value to the power sale meter 700 to determine the output power value output from the power supply device 11.
Therefore, instead of measuring the amount of power sold, the power sale meter 700 detects the power output from the power supply device, and multiplies the time when the power is detected (power sale time) by the output frequency value. Competence may be calculated.

Moreover, the power sale meter 700 notifies the facility meter 800 of the date and time when the power is output from the power supply device 11 (power sale date and time) as a result of power sale, and the facility meter side multiplies the power sale time by the output power value. Thus, the amount of electric power sold may be calculated.
<< 4. Embodiment 4 >>
If it is possible to sell power from a plurality of outlets provided in the facility at the same time, the convenience for the user is further improved. Therefore, in the power sale system of the fourth embodiment, the facility meter grasps the reverse power flow amount for each power sale meter by changing the frequency modulation of the output power for each power sale meter.

Hereinafter, the power selling system of the fourth embodiment will be described with reference to the drawings. In the power selling system of the fourth embodiment, the same reference numerals are given to components and processing steps that perform substantially the same processing as the power selling systems of the above-described embodiments, and the description thereof is omitted.
<4-1. Configuration>
FIG. 25 is a configuration diagram of the power selling system 4 according to the fourth embodiment.

The power sale system 4 is obtained by replacing the power sale meter 100 with the power sale meter 900 and replacing the facility meter 200 with the facility meter 1000 in the power sale system 1 of the first embodiment.
The power sale meter 900 is obtained by replacing the control unit 140 with the control unit 910 in the power sale meter 100 of the first embodiment.

The control unit 910 controls on / off of the power output of the power supply device 11 according to the authentication result of the start of power sale output from the inter-facility meter communication unit 130, similarly to the control unit 140 of the first embodiment. It has a function.
Then, the control unit 910 further acquires a notification of the output frequency value from the facility meter 1000 via the facility meter communication unit 130, controls the power supply device 11 to ON, and supplies the power supply device 11 with the acquired output frequency value. It has a function of performing control to output electric power.

The facility meter 1000 further includes an output control unit 1010 in the facility meter 200 of the first embodiment, replaces the reverse flow power amount measurement unit 220 with a reverse flow power amount measurement unit 1020, and replaces the storage unit 270 with the storage unit 1030. The verification unit 250 is replaced with a verification unit 1040.
The output control unit 1010 sets an output frequency value for each power sale meter 900, notifies the power sale meter 900 of the set output frequency value via the power sale meter communication unit 230, and sells the sale. It has a function of controlling the output frequency value of the power supply device 11 corresponding to the electricity meter 900.

However, the range of the output frequency value is defined as a rule for causing the commercial power system to reversely flow. Therefore, the output control unit 1010 sets the output frequency value notified to each power sale meter 900 within the specified range.
The reverse power flow amount measuring unit 1020 has a function of measuring the reverse power flow amount by distinguishing it for each frequency.

  Similar to the storage unit 270 of the facility meter 200 of the first embodiment, the storage unit 1030 measures the measurement result of the received power amount measurement unit 210, the measurement result of the reverse power flow amount measurement unit 1020, and the communication between power sale meters. A function of storing the measurement result of the amount of electric power sold acquired by the unit 230; However, the memory | storage part 1030 memorize | stores the measurement result of the reverse flow electric energy for every frequency measured in the reverse flow electric energy measurement part 1020.

Further, the storage unit 1030 has a function of storing a correspondence relationship between each power sale meter 900 and each output frequency value set by the output control unit 1010.
FIG. 26 is an example of information stored in the storage unit 1030. In FIG. 26, the device ID of the power sale meter 900 and the output frequency value set for each power sale meter 900 in the output control unit 1010 are stored in association with each other. Further, the measurement date and time and the reverse power flow amount are stored for each output frequency value as the measurement result of the reverse flow power amount.

Similar to the verification unit 250 of the facility meter 200 of the first embodiment, the verification unit 1040 has a function of verifying whether or not the measurement result of the power sale power amount by the power sale meter 900 is reliable. However, when power is sold by a plurality of power sale meters 900 at the same time, the verification unit 1040 performs verification processing for each power sale meter 900 in consideration of that.
<4-2. Operation>
FIG. 27 is a sequence diagram showing the overall operation of the power sale system 1.

The facility meter 1000 constantly measures and stores the amount of received power and the amount of reverse power flow (S0). Here, the reverse flow power amount is measured separately for each frequency, and the measurement results of the received power amount and the reverse flow power amount are used in the verification process (S43) in the verification unit 1040.
First, when the power sale meter 900 receives a request for starting power sale from the power supply device 11, the power sale meter 900 notifies the facility meter 1000 of the ID of its own device (S1).

  In response to this, the facility meter 1000 uses the ID of the power sale meter 900 notified in step S1 to confirm registration of whether or not the power sale meter 900 is registered in the server (S21). If the registration is not confirmed in step S21, the facility meter 1000 disallows the start of power sale via the power sale meter 900 and notifies the power sale meter 900 to that effect. On the other hand, if the registration is confirmed in step S21, the power sale meter 900 is notified of the output frequency value in order to modulate the power frequency to be output to the outlet (S41).

When receiving the notification of the power frequency value in step S41, the power sale meter 900 causes the power supply device 11 to output power at the power frequency (S42).
Subsequently, the power sale meter 900 measures the amount of power sold (S5), and notifies the facility meter 1000 of the measurement result (S6).
In response to this, the facility meter 1000 verifies whether or not the measurement result of the power sale power amount notified in step S6 is reliable (S44). In S44, the facility meter 1000 performs a verification process in the same manner as the facility meter 200 of the first embodiment. However, when power is sold by a plurality of power sale meters at the same time, the verification process is performed in consideration thereof.

Subsequently, the facility meter 1000 reports power sale to the server 300 according to the verification result of step S44 (S8), and then notifies the power sale meter 900 of establishment or non-establishment of power sale (S9).
In response, the power sale meter 900 notifies the user of the establishment or non-establishment of power sale (S10).

Next, specific operations of the power sale meter 900 and the facility meter 1000 will be described.
FIG. 28 is a flowchart showing the operation of the power sale meter 900.
The operation of the power sale meter 900 shown in FIG. 28 is obtained by replacing step S601 with step S901 and replacing step S602 with step S902 in the operation of the power sale meter 700 of the third embodiment shown in FIG. .

That is, after step S101, the inter-facility meter communication unit 130 does not receive the notification of permission to start power sale from the inter-power sale meter communication unit 230 of the facility meter 1000 (S401: NO), and notifies the output frequency value. If it receives (S901: YES), the control part 910 will output electric power to the power supply device 11 with the output frequency value (S902).
FIG. 29 is a flowchart showing an operation related to power sale of the facility meter 1000.

The operation of the facility meter 1000 shown in FIG. 29 is obtained by replacing step S701 with step S1001 and replacing step S702 with step S1002 in the operation of the facility meter 800 of the third embodiment shown in FIG.
That is, if the power sale meter 900 corresponding to the ID is registered in step S501A (S502A: YES), the output control unit 1010 uses the facility meter of the power sale meter 900 via the power sale meter communication unit 230. The inter-communication unit 130 is notified of the output frequency value (S1001).

  After step S1001, the power sale meter 900 performs power output control at the output frequency value notified in step S1001, and starts measuring the amount of power sold. When the power sale power amount measurement is completed, the power sale meter communication unit 230 acquires the power sale power amount measurement result from the facility meter communication unit 130 of the power sale meter 900 and outputs the measurement result to the verification unit 1040 (S205). ).

Subsequently, the verification unit 1040 verifies whether or not the output measurement result of the electric power sales power is reliable (S1002).
In S1002, the verification unit 1040 performs verification processing in the same manner as the verification unit 250 of the facility meter 200 according to the first embodiment.
As described above, according to the power selling system 4 of the fourth embodiment, the facility meter 1000 gives the output frequency value of the power to be output to the power supply device 11 for each power selling meter 900, thereby It becomes possible to verify the measurement result of the amount of electric power sold.

<4-3. Modification 1>
As described above, the range of the output frequency value is specified as the specification for causing the commercial power system to reversely flow. Therefore, in the said Embodiment 4, the output control part 1010 of the facility meter 1000 shall set the output frequency value notified for every power sale meter 900 within the prescription | regulation range. However, in the reverse flow electric energy measuring unit 1020, high measurement accuracy is required to distinguish and measure the reverse flow electric energy for each different frequency within the specified range.

Therefore, the output frequency value set by the facility meter 1000 is not within the specified range for causing the commercial power supply system to reversely flow, and instead, a frequency modulator is provided upstream of the reverse flow current measuring unit 1020, and the frequency modulation is performed. The device may modulate the frequency value of power supplied to the commercial power supply system within a specified range.
<4-4. Modification 2>
In the fourth embodiment, the control unit 910 of the power sale meter 900 has been described as performing the control to output power to the power supply device 11 with the output frequency value notified from the facility meter 1000. However, the present invention is not limited to this. The control unit 910 may be provided with a function of modulating the power frequency, and the control unit 910 may perform frequency modulation of the power output from the power supply device 11.

≪5. Supplement (Part 1) >>
(1) <1-4. Of the first embodiment. In Modification 2>, it has been described that the server may authenticate the start of power sale via the power sale meter.
Therefore, the power sale meter is provided with a means for communicating with the server, and at the start of power sale, the server is directly notified of the power sale meter ID without going through the facility meter, thereby requesting the authentication of the power sale start. And it is good also as acquiring the authentication result of a power sale start from a server, and performing the power output control of the power supply device 11 according to the result.

  (2) In each of the above embodiments, the facility meter is provided with a verification unit, and the facility meter verifies the reliability of the measurement result of the amount of power sold by the power sale meter. The server that performs this verification may perform this verification. The server may perform this verification by acquiring the measurement result of the power sale meter and the measurement result of the facility meter from the facility meter at once, or acquiring the measurement result from each of the power sale meter and the facility meter. That is, the measurement result of the power sale meter may be obtained directly from the power sale meter. In addition, the server may acquire the measurement result of the power sale meter via the mobile terminal.

  (3) Each component of each device shown in the modified examples and the like described in the above embodiments may be realized by an LSI (Large Scale Integration) which is an integrated circuit. At this time, each component may be individually made into one chip, or may be made into one chip so as to include a part or all of them. In addition, although it is referred to as LSI here, it may be referred to as IC (Integrated Circuit), system LSI, super LSI, or ultra LSI depending on the degree of integration. Further, the method of circuit integration is not limited to LSI, and implementation with a dedicated circuit or a general-purpose processor is also possible. An FPGA (Field Programmable Gate Array) or a reconfigurable processor capable of reconfiguring connection and setting of circuit cells inside the LSI may be used. Furthermore, if integrated circuit technology comes out to replace LSI's as a result of the advancement of semiconductor technology or a derivative other technology, it is naturally also possible to carry out function block integration using this technology.

(4) At least a part of the operation procedure of each device described in each of the above embodiments and modifications is described in a program. For example, a CPU (Central Processing Unit) reads and executes the program stored in a memory. The program may be stored in a recording medium and distributed.
(5) You may combine suitably the content demonstrated in said each embodiment, a modification, supplement, etc.

≪6. Supplement (Part 2) >>
The watt-hour meter, the watt-hour measurement system, and the watt-hour measurement method according to the above-described embodiments, modifications, and supplements (part 1) are summarized.
(1) The first watt-hour meter is a watt-hour meter that measures the amount of power sold by the user, and the power distribution device connected to the outlet in the facility is connected to the distribution network in the facility via the outlet. A measurement unit that measures the amount of power supplied to the power supply as a sale power amount, a control unit that controls the output of the power supply device, and an amount of power exchanged between a commercial power supply system and a distribution line in the facility A communication unit that communicates with an external system including at least a facility energy meter to be measured, and the communication unit notifies the external system of user information for specifying a user who performs the power sale. A result of user authentication based on the user information is acquired from the external system, and the control unit performs power output control of the power supply device based on the result of user authentication.

According to the first watt-hour meter, it is possible to measure the amount of power sold for each user. In addition, in the power sale through the outlet, it is possible to control the power output to the outlet and measure the amount of electric power sold.
(2) The second watt-hour meter is the first watt-hour meter, wherein the communication unit further notifies the measurement result of the measurement unit to the external system, and the reliability of the measurement result of the measurement unit is It is good also as verifying based on the measurement result of the watt-hour meter for facilities, and the measurement result of the measurement part.

According to the second watt-hour meter, the amount of power sold by the second watt-hour meter based on the measurement result of the amount of power exchanged between the commercial power supply system and the distribution lines in the facility by the facility watt-hour meter. It becomes possible to verify the reliability of the measurement results.
(3) The third watt-hour meter is the first watt-hour meter, wherein the communication unit further notifies the facility watt-hour meter of a test power amount to be output to the power supply device on a trial basis. The control unit receives the test power amount when the notification of the test power amount is received, and the communication unit further outputs the test power amount by the measurement unit. The measurement result of the electric energy is notified to the facility watt-hour meter, and the output authentication result of the power supply apparatus based on the measurement result of the test electric energy is acquired from the facility watt-hour meter. The power output control of the power supply device may be performed based on the result of the user authentication and the output authentication result of the power supply device.

  According to the third watt-hour meter, the power output authentication of the power supply device is performed according to the experimental measurement result of the power amount output from the power supply device, and the power output authentication result and the user authentication result are determined. Thus, the power output of the power supply device can be performed. For example, on the facility meter side, it is possible to perform control to output power to the power supply apparatus only when a power selling user is specified in user authentication and power output is recognized in power output authentication.

  (4) The fourth watt-hour meter is the second watt-hour meter, wherein the communication unit further receives a notification of an output power value to be output to the power supply device from the facility watt-hour meter, and the control The unit causes the power supply device to output power with the output power value, and the notification unit further notifies at least the power output time of the power supply device among the measurement results of the measurement unit, and the measurement unit measures The reliability of the result may be verified based on the measurement result of the facility watt-hour meter, the output power value, and the power output time of the power supply device.

  According to the fourth watt-hour meter, it is possible to perform control to output power to the power supply device with the output power value given from the facility meter. For example, the time when power is output from the power supply device (power sale) It is possible to calculate the amount of electric power sold by grasping (time). Therefore, the facility meter side can easily verify the reliability of the measurement result of the amount of power sold by the fourth watt-hour meter.

  (5) The fifth watt-hour meter is the second watt-hour meter, wherein the communication unit further receives a notification of an output frequency value to be output to the power supply device from the facility watt-hour meter, and the control The unit causes the power supply device to output power at the output frequency value, the notification unit further notifies the facility watt-hour meter of the measurement result of the measurement unit, and the test watt-hour meter The amount of power that flows backward to the distribution network in the facility is measured for each frequency value, and the reliability of the measurement result of the measurement unit is based on the measurement result of the facility watt-hour meter and the measurement result of the measurement unit May be verified.

  According to the fifth watt-hour meter, it is possible to control the power supply device to output power at the output frequency value for each watt-hour meter given from the facility meter, and from a plurality of outlets provided in the facility. Even if power is output at the same time, the facility watt-hour meter must grasp the power amount for each frequency value and verify the reliability of the measurement result of the power sale amount for each power meter. Is possible.

(6) The watt-hour meter according to any one of the first to fifth, wherein the sixth watt-hour meter is configured such that the communication unit transmits the user information to the external system via a portable terminal held by the user. May be notified.
According to the sixth watt-hour meter, the communication function of the sixth watt-hour meter can be simplified by using the communication function of the portable terminal.

(7) The seventh watt-hour meter is the watt-hour meter according to any one of the first to sixth aspects, wherein the communication unit further transmits the measurement result of the measurement unit via the portable terminal. Notification may be made to a server that manages electricity.
According to the seventh watt-hour meter, the communication function of the sixth watt-hour meter can be simplified by using the communication function of the portable terminal.

(8) The eighth watt-hour meter is the watt-hour meter according to any one of the first to sixth aspects, wherein the communication unit further transmits the measurement result of the measurement unit via the facility watt-hour meter. The server that manages the power sale may be notified.
According to the eighth watt-hour meter, it becomes possible for the mobile terminal to notify the server of the measurement result of the amount of power sold by the eighth watt-hour meter, and communication between the eighth watt-hour meter and the facility watt-hour meter is possible. The function can be simplified.

(9) The facility watt-hour meter is the facility watt-hour meter according to any one of the first to ninth aspects.
According to this facility watt-hour meter, it becomes possible to manage power sales through an outlet in cooperation with the watt-hour meter according to any one of the first to ninth.
(10) The first server device measures the amount of power supplied to the distribution network in the facility from the power supply device connected to the outlet in the facility through the outlet as the amount of power sold by the user. An acquisition unit that acquires user information for identifying the user who performs the power sale from the watt hour meter, and a list indicating whether or not the user is permitted to sell power for each of a plurality of users to be managed A storage unit for storing, and an authentication unit for performing authentication of power output by the power supply device based on the user information and the list are provided.

According to the first server device, it is possible to manage a power sale through an outlet by storing a list of users who sell power and a power meter used by the user.
(11) In the second server device, in the first server device, the watt hour meter performs power output control of the power supply device based on a result of the authentication, and the authentication unit includes:
The authentication may be further performed based on an instruction from an administrator of the commercial power system.

According to the second server device, it becomes possible for the server device side to restrict power sale through the outlet. For example, when the power supply state of the commercial power supply system is sufficient and it is not necessary to sell power through the outlet, the manager of the commercial power supply system can not permit power sale through the outlet. .
(12) The third server device measures the amount of power supplied from the power supply device connected to the outlet in the facility to the distribution network in the facility through the outlet as the amount of power sold by the user. From the watt-hour meter, the facility watt-hour meter acquires the measurement result of the watt-hour meter and measures the amount of power transferred between the commercial power supply system and the distribution line in the facility. An acquisition unit that acquires a measurement result of the meter, and a verification unit that verifies the reliability of the measurement result of the watt-hour meter based on the measurement result of the facility watt-hour meter and the measurement result of the watt-hour meter; , Comprising.

According to the third server device, the reliability of the measurement result of the electric power sales measured by the watt-hour meter is determined by the server device between the commercial power supply system and the distribution line in the facility by the facility watt-hour meter. It becomes possible to verify from the measurement result of the electric energy exchanged between the two.
(13) The power amount measurement system is a power amount measurement system that measures the amount of power sold by a user, and the power amount measurement system is connected to a power supply device connected to an outlet in a facility via the outlet. A watt-hour meter that measures the amount of power supplied to the distribution network in the facility as a sold power amount, and a facility power amount that measures the amount of power transferred between the commercial power supply system and the distribution lines in the facility The watt-hour meter communicates with an external system including at least the measurement unit that measures the amount of power sold, a control unit that controls output of the power supply device, and the facility watt-hour meter A communication unit, wherein the communication unit notifies the external system of user information for specifying a user who performs the power sale, and receives a result of user authentication based on the user information from the external system. And, wherein the control unit performs the power output control of the power supply device based on a result of the user authentication, and wherein the.

According to this power amount measurement system, it is possible to measure the amount of power sold for each user. In addition, in the power sale through the outlet, it is possible to control the power output to the outlet and measure the amount of electric power sold.
(14) The power amount measuring method is a power amount measuring method for measuring the amount of power sold by the user using the power amount measuring system, wherein the power amount measuring system is connected to a power supply device connected to an outlet in a facility. A watt hour meter that measures the amount of power supplied to the distribution network in the facility through the outlet as the amount of power sold, and the amount of power transferred between the commercial power supply system and the distribution line in the facility A watt-hour meter for a facility, the watt-hour meter measures the amount of power sold, controls the output of the power supply device, communicates with an external system including at least the watt-hour meter for facility, In the communication, the external system is notified of user information for specifying a user who performs the power sale, a result of user authentication based on the user information is acquired from the external system, and the control is performed. In performs power output control of the power supply device based on a result of the user authentication, and wherein the.

  According to this power amount measuring method, it is possible to measure the amount of power sold for each user. In addition, in the power sale through the outlet, it is possible to control the power output to the outlet and measure the amount of electric power sold.

  The present invention can be used in various facilities provided with an outlet.

1, 1A, 1B, 2, 2A, 3, 4 Power selling system 10 Photovoltaic power generation system 11 Power supply device 12 Terminal 20 Distribution board 30 Electricity meter for purchase and sale 40 Facility load group 50 Outlet 60 Network 70 Mobile terminal 100, 100A, 500, 700, 900, 1500 Power sale meter 110 Power sale power amount measurement unit 120 Power sale power amount storage unit 130 Facility meter communication unit 130A, 230A Mobile terminal communication unit 140, 510, 710, 910, 1520 Control unit 150 Outlet terminal 160 Power supply terminal 200, 200A, 200B, 600, 800, 1000, 1600 Facility meter 210 Received power amount measuring unit 220, 1020 Reverse power flow amount measuring unit 230 Inter-selling meter communication unit 240 Authentication unit 250, 820, 1040 Verification 260, 260B network Communication unit 270, 1030, 1550, 1620 storage unit 300, 400 server 410 user information storage unit 420 communication unit 430 authentication unit 610, 1610 authentication verification unit 810, 1010 output control unit 1510 switching unit 1530 power consumption unit 1540 power consumption Quantity measuring unit

Claims (14)

A watt-hour meter that measures the amount of power sold by a user,
A measurement unit that measures the amount of power supplied from the power supply device connected to the outlet in the facility to the distribution network in the facility through the outlet;
A control unit for controlling the output of the power supply device;
A communication unit that communicates with an external system including at least a watt-hour meter for a facility that measures the amount of power exchanged between a commercial power supply system and a distribution line in the facility;
With
The communication unit is
Notifying the external system of user information for specifying a user who performs the power sale,
Obtaining a result of user authentication based on the user information from the external system;
The controller is
Performing power output control of the power supply device based on the result of the user authentication;
Electricity meter. The communication unit further includes:
Notifying the external system of the measurement result of the measurement unit,
The reliability of the measurement result of the measurement unit is verified based on the measurement result of the facility watt-hour meter and the measurement result of the measurement unit,
The watt-hour meter according to claim 1. The communication unit further includes:
From the facility watt-hour meter, receiving a notification of the test power amount to be output to the power supply device on a trial basis,
The control unit further includes:
When the notification of the test power amount is accepted, the power source device outputs the test power amount,
The communication unit further notifies the facility watt-hour meter of the measurement result of the test electric energy by the measurement unit,
Obtaining the result of the output authentication of the power supply device based on the measurement result of the test electric energy from the facility watt-hour meter,
The control unit
Based on the result of the user authentication and the result of output authentication of the power supply device, power output control of the power supply device is performed.
The watt-hour meter according to claim 1. The communication unit further includes:
From the facility watt-hour meter, accept notification of the output power value to be output to the power supply device,
The control unit causes the power supply device to output power at the output power value,
The notification unit further includes:
Of the measurement results of the measurement unit, at least notify the power output time of the power supply device,
The reliability of the measurement result of the measurement unit is verified based on the measurement result of the facility watt-hour meter, the output power value, and the power output time of the power supply device.
The watt-hour meter according to claim 2. The communication unit further includes:
From the facility watt-hour meter, accept notification of the output frequency value to be output to the power supply device,
The control unit causes the power supply device to output power at the output frequency value,
The notification unit further includes:
Notifying the facility electricity meter of the measurement result of the measurement unit,
The test watt-hour meter is
Measure the amount of power that flows backward to the distribution network in the facility for each frequency value,
The reliability of the measurement result of the measurement unit is verified based on the measurement result of the facility watt-hour meter and the measurement result of the measurement unit,
The watt-hour meter according to claim 2. The communication unit is
Notifying the user information to the external system via a portable terminal held by the user;
The watt-hour meter in any one of Claim 1 to 5. The communication unit further includes:
Notifying the measurement result of the measurement unit to a server that manages the power sale via the portable terminal,
The watt-hour meter in any one of Claim 1 to 6. The communication unit further includes:
Notifying the measurement result of the measurement unit to a server that manages the power sale through the facility electricity meter,
The watt-hour meter in any one of Claim 1 to 6.   The facility watt-hour meter according to any one of claims 1 to 9. As the amount of electric power sold by the user, the electric power sold from a watt-hour meter that measures the amount of electric power supplied from the power supply device connected to the outlet in the facility to the distribution network in the facility through the outlet. An acquisition unit for acquiring user information for specifying a user to perform;
For each of a plurality of managed users, a storage unit that stores a list indicating whether or not the user is permitted to sell power;
An authentication unit that performs authentication of power output by the power supply device based on the user information and the list;
Server device. The watt hour meter performs power output control of the power supply device based on the result of the authentication,
The authentication unit
The authentication is further performed based on an instruction from the manager of the commercial power system.
The server device according to claim 10. From the watt-hour meter that measures the amount of power supplied to the power distribution network in the facility from the power supply device connected to the outlet in the facility as the amount of power sold by the user, the watt-hour meter Get the measurement result of
An acquisition unit that acquires a measurement result of the facility watt-hour meter from a facility watt-hour meter that measures the amount of power transferred between a commercial power supply system and a distribution line in the facility;
A verification unit that verifies the reliability of the measurement result by the watt hour meter based on the measurement result by the facility watt hour meter and the measurement result by the watt hour meter,
Server device. An energy measurement system for measuring the amount of power sold by a user,
The electric energy measurement system includes:
A watt-hour meter that measures the amount of power supplied from the power supply connected to the outlet in the facility to the distribution network in the facility through the outlet;
A facility watt-hour meter that measures the amount of power transferred between the commercial power supply system and the distribution lines in the facility,
The electricity meter
A measuring unit for measuring the amount of electric power sold;
A control unit for controlling the output of the power supply device;
A communication unit for communicating with an external system including at least the facility electricity meter;
With
The communication unit is
Notifying the external system of user information for specifying a user who performs the power sale,
Obtaining a result of user authentication based on the user information from the external system;
The controller is
Performing power output control of the power supply device based on the result of the user authentication;
Electric energy measurement system. An electric energy measuring method for measuring an electric energy sold by a user using an electric energy measuring system,
The electric energy measurement system includes:
A watt-hour meter that measures the amount of power supplied from the power supply connected to the outlet in the facility to the distribution network in the facility through the outlet;
A facility watt-hour meter that measures the amount of power transferred between the commercial power supply system and the distribution lines in the facility,
The electricity meter
Measure the amount of electricity sold,
Control the output of the power supply,
Communicate with an external system including at least the facility electricity meter,
In the communication,
Notifying the external system of user information for specifying a user who performs the power sale,
Obtaining a result of user authentication based on the user information from the external system;
In the control,
Performing power output control of the power supply device based on the result of the user authentication;
Electricity measurement method.

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