JP6128856B2 - Power network system - Google Patents

Description

  The present invention relates to a power supply control technique.

  With the recent increase in interest in energy problems, an increasing number of households own power generation devices such as solar power generation.

  Solar power generation can only be performed during the day when there is a lot of solar radiation, so it is possible to store electricity in a power storage device (battery) so that it can be used even at night or on cloudy days, or when the price of power increases. In some cases, electric power is sold by shifting the position (see Patent Document 1, etc.). Note that not only solar power generation but also the use of a power storage device is effective for efficient operation and smoothing of power generation device operation and power use.

JP 2011-130618 A

  Although it is effective to use the power storage device as described above, the power storage device is generally expensive and has a high threshold for purchase and installation by general users.

  Moreover, although the price per unit capacity decreases as the capacity of the power storage device increases, the capacity of the power storage device that exceeds the power generation capacity of the home is not used up and is wasteful. On the other hand, there are cases where the power storage device having a capacity lower than the power generation capacity at home cannot effectively use the power.

  Furthermore, the electric power stored at home can be used only at home, and when owning an electric vehicle or the like, it is not possible to meet the need to use the stored power on the go.

  The present invention has been proposed in view of the above-described conventional problems. The purpose of the present invention is to enable sharing of the power storage device, so that even a user who does not own the power storage device can store power. An object of the present invention is to provide an electric power network system that can be used and can promote the spread of large-capacity power storage devices.

In order to solve the above problems, in the present invention, a power supply that accepts a user-specified power supply request from any smart meter for the purpose of power storage for a shared power storage device connected on a smart grid network When a request for power supply is received and a request for power supply is received, the amount of power stored in the shared power storage device is investigated, and if there is a remaining power storage capacity, the permission of power supply is responded to the requesting smart meter A power supply responding means; a power storage control means for selecting the shared power storage device that performs power storage when permitting power supply and controlling power storage; a recording means for recording the amount of stored power for each user; Power procurement request means for accepting a user-specified power procurement request from any smart meter, and the user to request when a power procurement request is accepted Power procurement response means for responding to the smart meter requesting permission for power procurement within the range of the amount of unused power storage at the present time, and when allowing power procurement, the user's current unused power consumption A power return unit that supplies power from the shared power storage device within a range of power storage and updates a record of the amount of power stored for each user , the power supply response unit and the power procurement response unit are smart To grasp the power distance from the meter address and satisfy the request based on the selection probability set for each zone according to the power distance, giving priority to other smart meters with a power distance close to the requesting smart meter. Select another smart meter .

  In the power network system of the present invention, by enabling sharing of the power storage device, even a user who does not own the power storage device can store power and promote the popularization of large-capacity power storage devices. Can do.

It is a figure which shows the structural example of the electric power network system concerning one Embodiment of this invention. It is a figure which shows the example of the data which the control apparatus which a provider operates manages. It is a figure which shows the concept of the voltage maintenance in a smart grid network. It is a flowchart (the 1) which shows the process example of embodiment. It is a flowchart (the 2) which shows the process example of embodiment. It is a figure which shows the example of the setting of the hierarchical address for grasping | ascertaining electric power distance. It is a figure which shows the example of grasping | ascertaining the electric power distance by a hierarchized address. It is a flowchart which shows the process example of selection of the smart meter based on electric power distance. It is a flowchart which shows the process example of selection of the smart meter based on the selection probability according to electric power distance.

  Hereinafter, preferred embodiments of the present invention will be described.

<Configuration>
FIG. 1 is a diagram showing a configuration example of a power network system according to an embodiment of the present invention. A line connecting elements in the figure serves as both power supply and data communication.

  In FIG. 1, a smart grid network 1 that integrates a power transmission network and an information communication network is connected to a control device 21 of a business operator 2 and a power generation device 23 and a power storage device 24 via a smart meter 22. Yes. As the power generation device 23, a turbine generator or the like that can operate and generate power at any time is assumed.

  The smart grid network 1 is also connected to a large-scale power plant 3 operated by an electric power company or the like.

  In addition, smart meters 41A, 41B, 41C,... Of user homes 4A, 4B, 4C,. In the user home 4A, the power generation device 42A, the power storage device 43A, and the electrical product 44A are connected to the smart meter 41A. In the user home 4B, the power generation device 42B and the electrical product 44B are connected to the smart meter 41B. In the user home 4C, an electrical product 44C is connected to the smart meter 41C.

  The smart grid network 1 is connected to a smart meter 51 of a service station 5 that provides a charging service for an electric vehicle or the like, and the smart meter 51 is connected to a charging device 52. Note that the charging device 52 is for controlling quick charging and the like, and if it has a charging control function on the side of the electric vehicle or the like, it only needs to have equipment for simply connecting to the power line. The charging service for an electric vehicle or the like is not limited to the dedicated service station 5, and can be provided in an environment that can be connected to the smart grid network 1, such as another user's house, a workplace, or a hotel. Furthermore, not only charging to an electric vehicle or the like, but also discharging (electric power sharing) from the electric vehicle or the like can be performed from anywhere as long as the environment can be connected to the smart grid network 1.

  Of the above-described components, the control device 21 has the same configuration as a general computer. Further, the smart meters 41A to 41C and 51 have a function of measuring the amount of electric power passing through in addition to the same configuration as a general computer, and include a home gateway, a power meter, and a HEMS (Home Energy Management System). Plays a role as a controller.

  FIG. 2 is a diagram illustrating an example of data managed by the control device 21 operated by the operator 2.

  In FIG. 2, the control device 21 performs “user ID”, “smart meter ID”, “smart meter address”, “selection probability / response probability”, “storage amount”, “power sale condition”, “power sale amount, cost” for each user to be serviced. "Data on items such as" Purchase conditions "," Purchase amount and cost "are stored. “User ID” is information for identifying a user. “Smart meter ID” is information for identifying a smart meter under the management of the user. The “smart meter address” is information corresponding to the connection hierarchy in the smart grid network 1 of the smart meter. The “smart meter ID” can be omitted by providing the “smart meter ID” with hierarchical information of “smart meter address”. “Selection probability / response probability” is a probability that the smart meter is selected as a procurement side when a power supply request is issued or a supply side when a power supply request is issued, or an inquiry as a premise to be selected. This is setting information when the user sets the probability of response.

  “Storage amount” is the current storage amount of the user (a value obtained by subtracting the amount of power used from the amount of stored power). The “power sale condition” is a condition such as a price, a time zone, and an electric energy when the user wants to sell electric power from his / her stored power. “Amount of electricity sold, cost” is the amount of electricity sold and the cost (consideration) when electricity is sold. “Purchase conditions” are conditions such as price, time zone, and power amount when the user purchases power from another. “Purchased amount, cost” is the purchased amount and cost (consideration) when power is purchased.

  Further, the control device 21 holds data of items such as “power storage device ID”, “power storage amount, remaining power storage capacity”, “smart meter ID”, “owned user ID” for each shared power storage device (shared power storage device). ing. “Power storage device ID” is information for identifying a power storage device. In the case where the shared power storage device is owned by the user, a contract with the operator 2 side is made in advance. “Storage amount, remaining storage capacity” is the current storage amount and remaining storage capacity of the power storage device (the total capacity minus the stored amount). “Smart meter ID” is information for identifying the smart meter to which the power storage device is connected. The “owning user ID” is information for identifying a user who owns the power storage device provided for sharing the power storage device.

  In addition, the control device 21 holds data of items such as “power generation device ID”, “power generation condition”, and “smart meter ID” for each power generation device such as a turbine power generation device that can be used to make up for the shortage of power temporarily. ing. “Power generation device ID” is information for identifying a power generation device. The “power generation condition” is a condition such as the amount of power that can be generated by the power generation device, the cost, and the like. “Smart meter ID” is information for identifying the smart meter to which the power generation device is connected.

  In addition, the control device 21 temporarily compensates for the shortage of power, and “power company ID”, “power sale conditions”, “power sales amount, cost” for each power company that can purchase power as necessary. Data on items such as “purchase conditions”, “purchase amount, cost” is stored. “Power company ID” is information for identifying the power company. The “power selling condition” is a condition such as a price, a time zone, and an amount of power when the power company sells power. “Amount of electricity sold, cost” is the amount of electricity sold and the cost (consideration) when electricity is sold. “Purchase conditions” are conditions such as price, time zone, and power amount when the power company purchases power. “Purchased amount, cost” is the purchased amount and cost (consideration) when power is purchased.

<Operations during power supply and power procurement>
FIG. 3 is a diagram illustrating the concept of voltage maintenance in a smart grid network.

  In FIG. 3, the smart grid network 1 is maintained at a constant voltage by making the amount of power flowing in and the amount of power flowing out the same. Therefore, the control device 21 (FIG. 1) performs control so that the inflowing electric energy and the outflowing electric energy are the same. The inflow and outflow of power may be performed from anywhere in the smart grid network 1.

  FIG. 4 is a flowchart showing a processing example of the above-described embodiment, and shows a processing example when power is supplied to the smart grid network 1 from the user home 4 (4A, 4B,...) Having the power generation device. In the following description, the processing of the smart meter 41 (41A, 41B,...) Of the user's home 4 and the processing of the control device 21 of the business operator 2 will be described separately.

  In FIG. 4, when a need for power supply occurs due to generation of surplus power or the like at any of the user homes 4 and processing starts (step S101), the smart meter 41 displays the user ID and supply conditions (supply start time, supply A power supply request accompanied with a power amount or the like is made to the control device 21 via the smart grid network 1 (step S102). Here, all the power supply from the user's home 4 is intended for power storage, but the power supply request includes information such as whether the purpose is power storage or real-time power sale, You may make it isolate | separate subsequent processes according to the information.

  Next, the smart meter 41 receives a response from the control device 21 (step S103). The response includes a response that permits power supply and a response that rejects power supply.

  If the response is a rejection of power supply (No in step S104), the smart meter 41 performs a corresponding process (step S105). For example, if it is a type of power generation device that can forego generation, it does not start power generation, or if it is a type of power generation device that cannot forego generation, it discards the generated power or is otherwise available If there is a power storage device, a response is made such as whether to store power in the power storage device.

  When it is a response permitting power supply (Yes in step S104), the smart meter 41 causes the power generation device to generate power and transmits the generated power to the smart grid network 1 (step S106).

  Next, the smart meter 41 notifies the control device 21 of the user ID and the supplied power amount via the smart grid network 1 at the end of power supply or at an appropriate timing during power supply (step S107).

  On the other hand, when receiving the power supply request from the user home 4 (step S111), the control device 21 of the business operator 2 determines whether or not the user ID is registered (whether or not it is a service provision target) (step S111). S112). That is, it is determined whether or not a corresponding user ID exists as data for each user managed by the control device 21 (FIG. 2).

  When determining that the user ID is not registered (No in step S112), the control device 21 makes a response to reject the power supply request (step S113).

  When it is determined that the user ID is registered (Yes in step S112), the control device 21 investigates the state of charge of the shared power storage device (step S114). That is, the sum of the remaining power storage capacity of the data (FIG. 2) for each shared power storage device managed by the control device 21 is acquired.

  Next, the control device 21 determines whether or not there is a margin in the remaining storage capacity from the result of the storage amount status investigation, that is, whether or not the total remaining storage capacity is larger than the required amount of power (step S115).

  If it is determined that the remaining power storage capacity is sufficient (Yes in step S115), the control device 21 makes a response for permitting power supply (step S116).

  Next, the control device 21 selects a power storage device (single or plural) to be used for power storage (step S117) and performs power storage (step S118).

  If it is determined that there is no margin in the remaining storage capacity (No in step S115), it is determined whether or not it is possible to supply power to others (step S119). That is, it is determined in consideration of cost whether or not there is a request for power procurement from another user's home 4, service station 5, or large-scale power plant 3.

  When it is determined that power can be supplied to others (Yes in step S119), the control device 21 makes a response permitting power supply (step S120).

  Next, the control device 21 supplies power to the other user's house 4, the service station 5, and the large-scale power plant 3 (step S121). In this case, it can be considered that power is virtually transmitted from the power supply source to the power supply destination.

  If it is determined that power cannot be supplied to others (No in step S119), the control device 21 makes a response to reject power supply or consumes surplus power after making a response to permit power supply. (Discard) (step S122).

  Thereafter, when there is a notification of the user ID and the supplied power amount from the smart meter 41, the control device 21 receives this and adds the supplied power amount to the stored power amount (FIG. 2) associated with the user ID ( Step S123). Here, what is important is not only when power is actually stored in the power storage device (step S118), but also when power is not actually stored and supplied to others (step S121) or discarded (step S122). Is also recorded as the amount of electricity stored by the user. That is, when permitting power supply, it is treated as being stored for the user of the power supply source.

  FIG. 5 shows a processing example when power is procured from the smart grid network 1 at the user home 4 (4A, 4B, 4C,...) Or the service station 5.

  In FIG. 5, when a need for power procurement occurs due to the start of power use or the like at either the user home 4 or the service station 5 (step S201), the smart meter 41 (51) A power procurement request with conditions (procurement start time, amount of procurement power, etc.) is made to the control device 21 via the smart grid network 1 (step S202).

  Next, the smart meter 41 receives a response from the control device 21 (step S203). The response includes a response that permits power procurement and a response that rejects power.

  If the response is a rejection of power procurement (No in step S204), the smart meter 41 performs a corresponding process (step S205). For example, whether to give up procurement from the smart grid (including a case where it is shifted to another time) or to use another available power storage device, etc. is taken.

  When it is a response permitting electric power procurement (Yes in step S204), the smart meter 41 starts using electric products and performs electric power procurement (step S206).

  Next, the smart meter 41 notifies the control device 21 via the smart grid network 1 of the user ID and the procured power amount at the end of power procurement or at an appropriate timing during power procurement (step S207).

  On the other hand, when receiving the power procurement request from the user home 4 (step S211), the control device 21 of the business operator 2 determines whether or not the user ID is registered (whether or not it is a service providing target person) (step S211). S212).

  When determining that the user ID is not registered (No in Step S212), the control device 21 makes a response to reject the power procurement request (Step S213).

  If it is determined that the user ID is registered (Yes in step S212), the control device 21 includes the requested power amount within the range and the excess amount of the user's power storage amount (if it falls within the range, there is no excess amount). (Step S214).

  Within the range of the user's power storage amount, the state of power storage of the shared power storage device is investigated (step S215). That is, the sum total of the storage amount of data (FIG. 2) for each shared power storage device managed by the control device 21 is acquired.

  Next, the control device 21 determines whether or not there is a margin in the amount of electricity stored, that is, whether the total amount of electricity stored is larger than the required amount of power from the result of the state of electricity storage state survey (step S216).

  When it is determined that there is a margin in the amount of power storage (Yes in step S216), the control device 21 makes a response that permits power procurement for the power storage amount of the user (step S217).

  Next, the control device 21 selects the power storage device (s) to be used for discharging (step S218), and performs power supply (discharge) from the power storage device (step S219).

  When it is determined that there is no surplus in the amount of stored electricity (No in step S216), a response for permitting electric power procurement is made (step S220), and a power generator such as a turbine power generator is driven to supply power, or Electric power is supplied depending on whether procurement is performed from the large-scale power plant 3 or from other user's home 4 (step S221). Note that costs are taken into account when deciding from which to procure.

  As described above, in principle, the user's power storage is returned from the shared power storage device, but even if the shared power storage device has no power margin, it is procured from other sources to supply power. .

  In addition, regarding the excess from the range of the amount of electricity stored by the user, the control device 21 sells power from the amount of electricity stored by another user (only when there is a margin in the amount of electricity stored), or generates power from a turbine power generator or the like. Determine whether it is possible to procure power by driving the device, procuring from a large-scale power plant 3 of an electric power company, or procuring from another user's home 4 in consideration of cost (Step S222).

  When it is determined that the procurement is not possible (No in step S222), the control device 21 makes a response to reject the power procurement request for the excess (step S223).

  If it is determined that procurement is possible (Yes in step S222), the control device 21 makes a response permitting a power procurement request for the excess (step S224).

  Next, the control device 21 procures electric power from any other and supplies electric power (step S225).

  After that, the control device 21 receives the user ID and the procurement power amount from the smart meter 41, and receives the notification, and if it is within the range of the user's power storage amount, the power storage amount associated with the user ID ( 2) Subtract the procurement power amount, record the purchase amount and cost in association with the user ID for the excess, and record the power sale amount and cost in the ID if there is another user who sold power to the user (Step S226).

  As mentioned above, although the example of a process when a power supply needs generate | occur | produces in a user's house etc. and a power procurement needs generate | occur | produced, it settles at a predetermined timing (for example, once a month).

  For example, if the idea of providing a power storage service to a user is taken, a charge (amount of use of a virtual power storage device) corresponding to the power storage amount and the power storage period can be imposed for each user. In addition, if the idea is to use the power stored by the user as a bank deposit and use it as a source of profit by operating it (selling power to other users, etc.), a virtual power storage device can be provided free of charge to the user. It can be used, or a part of the profit can be paid as interest.

  In addition, a user who provides his / her own power storage device as a shared power storage device can be paid according to the power storage capacity or can use a power storage service free of charge.

  In addition, when the stored power is sold, the cost is paid to the user who sold the power.

  In addition, the supplier who supplied power from other than the charged amount is charged for the sale of electricity, and the purchaser is required to pay the consideration.

  In the above embodiment, the case where there is a single operator 2 has been described. However, a single smart grid network 1 is multiplexed by adding information that can identify the operator to communication data flowing through the smart grid network 1. Thus, a plurality of business operators 2 can provide the same service in parallel.

  Also, a part of the functions of the smart meters 41A to 41C, 51 may be realized as a cloud service by a server on the network, and the smart meter may use these functions.

  In the above embodiment, a so-called central control type configuration in which the control device 21 performs control is shown. However, data and processing functions held by the control device 21 are distributed to each smart meter, and the same is performed in an autonomous and distributed manner. It can also be configured to perform the above processing (autonomous distributed type). For example, in FIG. 4, the smart meter 41 that has generated power supply needs also operates as the control device 21 in FIG. 4 and determines another smart meter that receives power by communicating with another smart meter. it can. Similarly, the smart meter 41 having the power procurement needs in FIG. 5 also operates as the control device 21 in FIG. 5 and determines another smart meter that communicates with another smart meter and supplies power. Can do. Moreover, it is good also as a form which mixed the central control type and the autonomous distributed type.

<Operations such as selecting other smart meters>
When selecting a smart meter that becomes a procurement side when an electric power supply request is made or a supply side when an electric power procurement request is made, that is, a storage amount state investigation and an electric storage device selection in FIG. 4 (step S114, S117), determination of whether power can be supplied to others, and power supply (steps S119, S121), investigation of the amount of stored electricity and selection of power storage devices in FIG. 5 (steps S215, S218), procurement from others (step S221) 5, in the determination of the possibility of power procurement and power procurement (steps S222 and S225), in addition to the power sale conditions and purchase conditions, “power distance” representing the degree of distance between the power inflow source and the power outflow destination. By taking into account, it is possible to reduce power loss during power transmission and improve efficiency.

  In the smart grid network 1, even if power flows out from another smart meter in response to power flowing in from one smart meter, power does not flow directly between the two. Only the flow is recognized. However, when there is a local bias between power supply and consumption (procurement) from a macro perspective, power loss becomes a problem. Therefore, by introducing “power distance” and making the power supply and consumption areas closer, it is possible to reduce power loss and improve efficiency.

  FIG. 6 is a diagram showing an example of setting a hierarchical address for grasping the electric power distance, and the upper address of the address from a predetermined starting point (starting from a large-scale power plant in the illustrated example) to a main branching point. Unique numbers are set in order. In the illustrated example, the smart meter address of the user home S is “128.25.66.3”, the smart meter address of the user home A is “128.25.66.1”, and the smart meter address of the user home B is “128.25.67.35”. ", The smart meter address of user home C is set to" 128.26.88.22 ", and the smart meter address of user home D is set to" 129.31.12.7 ".

Here, when the smart meter at the user's home S becomes the request source for the power supply request or the power procurement request, the other party's candidate is the smart meter at the user's home A, B, C, D, and between the smart meter addresses When collating
SA-A Longest Match at 128.25.66.xx
Longest Match with S-B 128.25.xx.xx
Longest Match with S-C 128.xx.xx.xx
It can be judged that there is a disagreement between S and D, and that the regions are geographically close in order of the highest number of matches from the top. FIG. 7 shows the zones divided according to the power distances from the smart meters in the user homes A, B, C, and D with the smart meter in the user home S as the center.

  FIG. 8 is a flowchart showing a process example of selecting a smart meter based on the power distance.

  In FIG. 8, first, a smart meter that is a candidate on the request side is identified (step S301), and a power distance between the requesting smart meter and the candidate smart meter is acquired (step S302). And it selects preferentially from the smart meters with short electric power distance (step S303).

  FIG. 9 is a flowchart showing a processing example of selection of a smart meter based on a selection probability according to the power distance.

  That is, in the case of the above-described method of selecting candidate smart meters in order from the shortest power distance, when there is a heavy user whose power supply or consumption is constantly very large, other smart meters in the vicinity frequently As a result, the use of resources as a whole system is biased. Therefore, the problem can be solved by selecting another smart meter based on the selection probability according to the power distance.

  In FIG. 9, first, a smart meter that is a candidate on the request side is identified (step S311), and the power distance between the requesting smart meter and the candidate smart meter is acquired (step S312). And it selects from the smart meter used as a candidate based on the selection probability according to electric power distance (Step S313).

  The relationship between the power distance and the selection probability is set as follows, for example. The zones are assumed to be those shown in FIG.

Zone # 1 selection probability: 1/10
Zone # 2 selection probability: 1/50
Zone # 3 selection probability: 1/100
Zone # 4 selection probability: 0

  Although the case where the selection probability is fixedly associated with the power distance zoning is illustrated, the selection probability may be changed in consideration of the frequency of occurrence of the power supply request and the power procurement request. In this case, the selection probability is changed to be lower as the frequency of the power supply request and the power procurement request is higher. As a result, the smart user in the neighborhood often responds to the light user, and many smart meters respond to the heavy user instead.

  Note that the above processing assumes that the control device 21 makes a selection in consideration of the selection probability, but when making an inquiry to the smart meter prior to determining a candidate, the request source smart meter address is also included. The smart meter that received the inquiry may grasp the power distance and the frequency of the request, and then return a response with a response probability corresponding to the selection probability described above. In this case, a smart meter that has responded may be selected.

  In addition, the selection probability / response probability is not limited to the case where the selection probability / response probability is determined according to the power distance or the request frequency, and can be set by the user who manages each smart meter. For example, it is possible to simply set a response probability, specify a request source to be allowed or rejected, attach a condition such as a time zone or electric energy, or a combination thereof.

<Summary>
As described above, according to the present embodiment, there are the following advantages.
(1) Even a user who does not own a power storage device can perform power storage, and can effectively use the power generated at home for self-use, power sale, or the like.
(2) If you can connect to the smart grid, you can use your charge anywhere. For example, it is possible to charge an electric vehicle from its own stored electricity on the go.
(3) Sharing power storage devices makes it possible to introduce a mechanism that returns profits to power storage device owners, and costs can be recovered even if large-capacity power storage devices are purchased. Promoted.
(4) The peak power can be smoothed by the presence of the power storage device, which can contribute to efficient power sharing.
(5) By determining the partner smart meter to satisfy the power supply request and the power procurement request according to the power distance, the power loss of the entire system can be reduced and the efficiency can be improved.
(6) Concentration of usage on smart meters around heavy users by determining the partner smart meter to satisfy the power supply request and power procurement request based on the selection probability / response probability according to the power distance and request frequency Can be prevented.
(7) By allowing the user to set the selection probability / response probability, the system can be operated with respect to the user's intention.

  The present invention has been described above by the preferred embodiments of the present invention. While the invention has been described with reference to specific embodiments, various modifications and changes may be made to the embodiments without departing from the broad spirit and scope of the invention as defined in the claims. Obviously you can. In other words, the present invention should not be construed as being limited by the details of the specific examples and the accompanying drawings.

DESCRIPTION OF SYMBOLS 1 Smart grid network 2 Operator 21 Control device 22 Smart meter 23 Power generation device 24 Power storage device 3 Large-scale power plant 4, 4A-4C User home 41, 41A-41C Smart meter 42, 42A, 42B Power generation device 43, 43A Power storage device 44, 44A-44C Electrical product 5 Service station 51 Smart meter 52 Charging device

Claims (8)

A power supply request accepting means for accepting a power supply request specifying a user from any smart meter for the purpose of power storage for a shared power storage device connected on a smart grid network;
A power supply response means for investigating the state of charge of the shared power storage device when a request for power supply is received and responding to the requesting smart meter for permission to supply power when there is a margin in the remaining power storage capacity; ,
A power storage control means for selecting the shared power storage device that performs power storage and controlling power storage when permitting power supply; and
Recording means for recording the amount of stored electricity for each user;
A power procurement request means for accepting a user-specified power procurement request from any smart meter;
When receiving a request for power procurement, a power procurement response means for responding to the requesting smart meter with permission for power procurement within the current unused storage amount of the requesting user;
A power return means for supplying power from the shared power storage device within the range of the current unused storage amount of the user when permitting power procurement, and updating a record of the stored energy amount for each user; equipped with a,
The power supply response unit and the power procurement response unit grasp a power distance by a smart meter address, give priority to another smart meter having a power distance close to the request source smart meter, or for each zone corresponding to the power distance. A power network system , wherein another smart meter for satisfying the request is selected on the basis of the selection probability set in (1) . The power network system according to claim 1,
A power network system comprising power selling means for selling power from a stored amount of the user under conditions desired by the user. In the electric power network system as described in any one of Claim 1 or 2,
A power network system comprising power supply means for supplying power stored in the shared power storage device to another power procurement request source. The power network system according to any one of claims 1 to 3,
The power supply response means supplies power when there is a margin in the remaining storage capacity of the shared power storage device and when there is no margin in the remaining storage capacity but a request for power procurement is available and power supply is possible. In response to the requesting smart meter,
The power storage system, wherein the power storage control unit does not store power to the shared power storage device. In the electric power network system according to any one of claims 1 to 4,
The power network system according to claim 1, wherein the power return unit performs power supply from a power supply source other than the shared power storage device when permitting power procurement and the power storage amount of the shared power storage device is insufficient. In the electric power network system as described in any one of Claims 1 thru | or 5,
The power supply response means and the power procurement response means select another smart meter to satisfy the request based on the probability according to the power distance to the request source smart meter and the request frequency. Power network system. In the electric power network system as described in any one of Claims 1 thru | or 5,
The power supply system according to claim 1, wherein the power supply response unit and the power procurement response unit select another smart meter to satisfy the request based on a probability set by a user who manages the smart meter. A power supply request accepting means for accepting a power supply request specifying a user from any smart meter for the purpose of power storage for a shared power storage device connected on a smart grid network;
A power supply response means for investigating the state of charge of the shared power storage device when a request for power supply is received and responding to the requesting smart meter for permission to supply power when there is a margin in the remaining power storage capacity; ,
A power storage control means for selecting the shared power storage device that performs power storage and controlling power storage when permitting power supply; and
Recording means for recording the amount of stored electricity for each user;
A power procurement request means for accepting a user-specified power procurement request from any smart meter;
When receiving a request for power procurement, a power procurement response means for responding to the requesting smart meter with permission for power procurement within the current unused storage amount of the requesting user;
A power return means for supplying power from the shared power storage device within the range of the current unused storage amount of the user when permitting power procurement, and updating a record of the stored energy amount for each user; equipped with a,
The power supply response unit and the power procurement response unit grasp a power distance by a smart meter address, give priority to another smart meter having a power distance close to the request source smart meter, or for each zone corresponding to the power distance. A power network control device that selects another smart meter for satisfying the request based on the selection probability set in (1) .