JP2012055087A - Power network control network - Google Patents

Abstract

PROBLEM TO BE SOLVED: To effectively utilize the generated power of a power supply source to the most by optimizing power transmission loss as the entire power network.SOLUTION: A smart meter 2 is fitted to a power consumption source or a power supply source 1, and each smart meter 2 is connected to a power transmission network 3 and a control network 4. The entire network is divided into a plurality of areas, and further, each area is divided into a plurality of zones. The smart meter 2 advertises a required electric energy or the electric energy that can be supplied in an own zone periodically, meanwhile, it responds to the received advertisement information based on own power demand/supply information. Matching of power demand is carried out in a distributed manner within a zone, for promoting optimization of power consumption quickly, and to reduce a transmission loss caused by long-distance transmission of electric power. In an area, an area broker installed for each area centrally manages power demand/supply among zones.

Description

  The present invention relates to the configuration of a control network of a power network aimed at leveling the peak of power consumption by determining power distribution based on the nature of each of various types of power supply sources such as natural energy, fossil fuel, and nuclear power. .

  Conventional power grids are based on the premise that large amounts of power from large-scale power plants such as thermal power plants and nuclear power plants will be distributed to a large number of small users such as households. It was not designed in consideration of the existence of a small-scale power generation source such as a small gas turbine.

  Patent Documents 1 and 2 have been proposed as systems for supplying power between a plurality of power generation companies and a plurality of consumers.

JP 2000-333369 A JP 2002-123578 A

  As a trend in recent years, due to increasing interest in energy issues, attention has been focused on renewable energy such as wind and solar power generation from conventional thermal and nuclear power generation. Conventional power networks centered on thermal power and nuclear power generation use an architecture that supplies power to a large number of users (sinks) from a source with a very large power supply capacity. On the other hand, in the future power grid, since power is supplied from wind power and solar power generation, as well as fuel cells and plug-in hybrid vehicles in each home, each one is small but many sources are many. The architecture supplies power to the sink. For such a multi-source / multi-sink architecture, there is a problem of efficiently controlling the power network and optimizing the total power consumption.

  Therefore, according to the present invention, by performing power distribution based on the nature of the power supply source and power consumption source, which have not been considered in the past, waste of power consumption in the entire power network and imbalance of power consumption due to time occur. The object is to provide a power network control network that can be solved.

In order to solve the above-described problem, a smart meter installed in a power consumption source or a power supply source and connected to a power transmission network and a control network, between the power consumption source or the power supply source and the power transmission network. The power supply / demand information, which is information indicating the amount of power required or available for the power consumption source or power supply source, is output to the control network and advertised to other smart meters. And a smart meter having a function of responding to the received power supply / demand information of another smart meter based on its own power supply / demand information, and connected to the plurality of smart meters and output from each smart meter. A power supply / demand information transferred from the power supply / demand information received from the control network. And it controls the power supply and demand in the consumption source or power supply.
Further, the control network is divided into a plurality of first areas, and power distribution in the first areas is controlled intensively by a server provided for each first area, and the first area is further controlled. The smart meter is divided into a plurality of second regions, and power distribution in the second region is distributedly controlled by the smart meter performing flooding advertisement of the power supply and demand information.
Furthermore, the power distribution is determined based on the amount of power consumption, the amount of power that can be supplied, and the properties of each power consumption source or power supply source.
Furthermore, the smart meter includes a distribution company designating unit and means for receiving only power supply and demand information from a user of the distribution company set by the distribution company designating unit, and virtually divides each power distribution company. The control network is realized.

According to the power network control network of the present invention, not only the power generation amount / consumption amount but also the distance between the power supply source and the power consumption destination is considered, and the transmission loss of the entire power network is optimized, and the generated power of the power supply source Can be used to the maximum extent possible.
Moreover, the total power consumption can be optimized by combining wide-area optimization based on centralized control and local optimization based on distributed control.
Furthermore, power consumption can be reduced by leveling power consumption by performing temporal power scheduling by the management server and distributed power interchange in the vicinity.
Furthermore, from a power network of a power company, etc., to a user (home, office, etc.), a 1: N-type tree-structured power network, a small-scale power generation source such as solar power generation at home or a small gas turbine It is possible to construct a new M: N type power network including a power supply source that has not been considered in the past, and a low-cost virtual between the power supply source and the user according to the distance (user position) and the required power A transmission line can be provided.

It is a figure for demonstrating schematic structure of the electric power network control network of this invention. It is a figure which shows the structure of the electric power network control network of this invention. It is a figure for demonstrating the advertisement of the electric power supply-and-demand information in a zone. It is a figure which shows an example of an internal structure of a smart meter. It is a flowchart which shows the flow of the matching process (power supply-and-demand control process in a zone) in a zone. It is a figure for demonstrating the example of a request | requirement operation | movement in a zone. It is a figure for demonstrating the interchange of the electric power in an area. It is a figure which shows an example of a structure of an area broker. It is a figure which shows an example of a time schedule table. It is a figure which shows an example of an energy QoS table. It is a figure which shows an example of the algorithm for determining distribution of electric power in an area broker. It is a figure which shows the other example of the algorithm of an electric power reservation. It is a figure which shows an example of an actual electric power network. It is a figure for demonstrating a virtual power network. It is a figure which shows an example of an internal structure of a smart meter.

With reference to FIG. 1, a schematic configuration of a power network control network of the present invention will be described.
In this figure, 1 is a power consumption source (customer), a power supply source (power generation source), or a home or office that is both a power consumption source and a power supply source (hereinafter referred to as “power consumption source or power supply source”). (In some cases, it is simply called “home” to avoid complications.) Here, there are various power generation sources such as a solar power generation system, a small gas turbine, and a fuel cell.
Each power consumption source or power supply source 1 is provided with a smart meter 2, and each power consumption source and power supply source 1 are connected to the power transmission network 3 via the smart meter 2.
The power transmission network 3 connects each power consumption source or power supply source 1 in a mesh form via the smart meter 2, and transmits power between the power consumption source or power supply source 1. Although not shown, the power transmission network 3 includes facilities of a power distribution company that manages the power transmission network.

The smart meter 2 has a function of acquiring power supply and demand information of each home and outputting it to a communication network, a control function of each household equipment, a reservation in the time axis direction of a power source, a use reservation function of home appliances, etc. It has.
The smart meter 2 is also connected to a control network 4. The control network 4 is a communication network configured in the same mesh shape as the power transmission network 3 that uses each smart meter 2 as a node and connects the nodes. The control network 4 can be realized by, for example, the Internet.
In the present invention, the power supply of the power network composed of the power consumption source or power supply source 1, the smart meter 2 and the power transmission network 3 is controlled using the network composed of the control network 4 and the smart meter 2.

FIG. 2 is a diagram showing the configuration of the power network control network of the present invention.
As shown in the figure, in the power network control network according to the present invention, a plurality of wide-area first power networks 10 (networks composed of a power consumption source and power supply source 1, a smart meter 2, and a power transmission network 3) called an area are controlled. It is divided into one area 21 to 24, and each area 21 to 24 is further divided into a plurality of local second areas called zones. FIG. 2 shows only a state where the area 22 is divided into a plurality of zones 31 to 34, but the other areas 21, 23 and 24 are similarly divided into a plurality of zones. The zone is, for example, an area of about 10 to 20 houses, and the area is, for example, an area at a municipal level.
Each of the areas 21 to 24 is provided with an area broker 40 that is a server that centrally controls power distribution in the area. The area broker 40 is provided in a data center, for example.

  In the power network control network of the present invention configured as described above, in each zone, each smart meter 2 controls the power supply and demand by distributed control by advertising the necessary power amount or the power amount that can be supplied. Then, electric power supply and demand is controlled by centralized control by the area broker. When power distribution between areas is necessary, adjustment is made between area brokers.

First, a method for controlling power supply and demand in the zone will be described.
The smart meter 2 provided in each household (power consumption source or power supply source) 1 advertises power supply / demand information including information on the amount of power that can be supplied or the required power consumption in its own zone, Then, a response is made to the received advertisement information based on its own power supply and demand information. This enables power demand matching in a distributed manner within the zone to optimize power use at high speed without using a central server and reduce power transmission loss due to long-distance transmission of power. . In addition, the power supply and demand information includes information on time constraints that require power, and information on the nature of the power supply source (controllable, dependent on the natural environment, CO ₂ emissions, etc.) It may be.

  With reference to FIG. 3 to FIG. 6, optimization of power use in a zone by advertising power supply and demand information will be described. The purpose of intra-zone optimization is to reduce transmission loss due to long-distance transmission of power by performing multi-source multi-sync optimization locally in the zone.

  FIG. 3 is a diagram showing an advertisement of power supply and demand information in the zone. As shown in the figure, smart meters 51 to 57 belonging to this zone are present in the zone 30. Each of the smart meters 51 to 57 transmits a packet 60 describing power supply / demand information of a home (power consumption source or power supply source) managed by the smart meter 51 to an adjacent smart meter in the zone 30. When each of the smart meters 51 to 57 receives the packet 60, each smart meter 51 to 57 performs matching between its own power supply / demand information and the power supply / demand information described in the received packet 60, and updates the power supply / demand information of the received packet 60. To flood. That is, the packet 60 describing the updated power supply / demand information is transmitted to all adjacent smart meters other than the smart meter that transmitted the received packet. By doing so, the power demand converges after a certain period of time, and power interchange between the power consumption sources or power supply sources 1 belonging to this zone is performed. The smart meters (nodes) in the same zone always communicate with each other, and each of the smart meters 51 to 57 acquires information on excess / shortage of power in all the smart meters in the zone.

FIG. 4 is a diagram illustrating an example of the internal configuration of the smart meter.
As shown in this figure, the smart meter 70 controls each part in the smart meter 70 and is installed in a home or office (power consumption source or power supply source) 1 in which the smart meter 70 is provided. Connected to the installed equipment by Zigbee or Ethernet (registered trademark), connected to the control unit 71 for controlling the operation of the equipment, the domestic distribution line connected to the equipment and the power transmission network 3, A usage status processing unit 72 that acquires information on the suppliable amount and the required power consumption amount, and a communication unit 73 connected to the control network 4 are provided. The smart meter 70 can monitor power consumption or power generation by the use status processing unit 72 and can grasp the energy status in the home by the control unit 71 connected to sensors and devices in the home. .

  The smart meter 70 grasps the amount of power that it can supply or needs by the usage status processing unit 72, and supplies power supply and demand information from the communication unit 73 to neighboring smart meters through the control network 4 such as the Internet. advertise. The smart meter that has received the power supply / demand information matches its own suppliable power amount or required power amount with the received information, and further advertises the subtracted power supply / demand information to the neighborhood.

An example of the matching process will be described with reference to FIGS.
FIG. 5 is a flowchart showing the flow of the matching process (power supply / demand control process in the zone) in the zone. In this figure, steps S1 and S2 are processes executed in a request node (smart meter) that makes a power supply request, and steps S3 to S7 are executed in a node (smart meter) other than the request node in the zone. It is processing.

When a power supply request occurs in a smart meter attached to a certain power consumption source or power supply source (S1), the smart meter (request node) searches for a power supply destination by flooding (S2). That is, a power supply / demand information packet including the generated supply request is generated and transmitted to an adjacent node. The power supply information includes, for example, information on the amount of power required and the number of hops of the node.
The node that has received the packet from the request node determines whether or not the node has a supply capability corresponding to the power demand contained in the packet (S3). A packet is generated and transmitted to the request node (S7). This response packet includes information such as the amount of power that can be supplied by the node, the number of hops of the node, and the identification number SID (smart meter ID) of the node (smart meter) that transmits this response packet.

  When the own node does not have the supply capability for the power demand, the number of hops included in the power supply / demand information is incremented by 1 (S4), and whether or not the number of hops is smaller than a predetermined hop limit number. Is determined (S5). When the hop count is smaller than the hop limit count, the power supply / demand information including the updated hop count is flooded to the adjacent node (S6). On the other hand, when the number of hops is greater than or equal to the hop limit number, the process is terminated without flooding.

  This will be specifically described with reference to FIG. FIG. 6A is a diagram illustrating an example of power supply / demand information transferred by flooding between the nodes, and FIG. 6B is a diagram illustrating in plan view how the power supply / demand information is flooded.

A smart meter that has generated a power supply request is referred to as node A. Node A floods an adjacent node (node B, node D) with a power supply request (power supply / demand information including information on the amount of power required). That is, the node A transmits a power supply and demand information packet including information on the required power amount to all adjacent nodes. FIG. 6A shows a state in which the power supply / demand information packet 61 including the amount of power “−10 kWh” required by the node A and the number of hops “1 hop” of the node A is transmitted to the nodes B and D. It is shown.
The adjacent nodes (node B, node D,...) Of node A that has received the packet 61 from the node A determine whether or not the node has the capability of supplying the requested power. In the example illustrated in FIG. 6, the node B does not have a supply capability, but the node D has a sufficient supply power and can supply power to the node A. In this case, the node B increments the number of hops included in the received packet 61 by “2 hops”, and the number of hops incremented by +1 is smaller than the preset hop limit number. The power supply / demand information packet 63 including “-10 kWh” and the number of hops “2 hop” of the node is transmitted to an adjacent node other than the node A (such as the node C).

Node D is assumed to be capable of supplying 10 kWh or more of power required by Node A. At this time, the node D creates and transmits a response packet 62 including the amount of power “+10 kWh” that can be supplied to the node A and the number of hops “1 hop” of the node. Since all the amount of power required by the node A can be supplied, the packet received from the node A is not flooded to other adjacent nodes.
Further, it is assumed that the node C that has received the packet 63 of the power supply / demand information flooded by the node B has sufficient power similarly to the node D and can supply the power requested by the node A. At this time, like the node D, the node C creates and transmits a response packet 64 of the amount of power supplied to the node A “+10 kWh” and the number of hops “2 hop” of the node. Further, the packet 63 received from the node B is not flooded to an adjacent node.

The response packet 62 from the node D and the response packet 64 from the node C are transmitted to the node A that is the request node, but the node A receives the response packet 62 having a smaller number of hops included in the response packet. Select and send a packet including information indicating that the response packet 62 has been selected (reception of power supply of 10 kWh from the node D) to the node D or advertise to all the nodes including the node D To do. As a result, the smart meter at node D supplies 10 kWh of power to the smart meter at node A via the power transmission network 3.
In the above, the case where the matching process is performed according to the power supply and demand information transmitted from the smart meter in which the power supply request is generated has been described, but the information on the amount of power that can be supplied from the smart meter having the power supply capability is included. The matching process is similarly performed when a smart meter that requires power returns a response packet in accordance with the power supply / demand information.
In this way, power generated by a solar panel or the like can be consumed locally within the zone, and power transmission loss due to long-distance transmission of power can be reduced.

  In this embodiment, by setting the hop limit number, a signal that exceeds a certain number of hops, that is, a signal that exceeds the upper limit that may not receive energy supply in the vicinity is not flooded. However, the hop limit number may not be set, and energy may be received from all smart meters in the zone.

Since the intra-zone optimization described above is based on immediate local matching, it is difficult to optimize a large deviation in power supply and demand in the zone and variations in power usage in the time axis direction. Therefore, the area broker optimizes power supply and demand in a wide area within the area.
As described above, each area is provided with an area broker that manages power supply and demand in the area and performs wide-area optimization in the area. The area broker is connected to a node (representative node) defined as a representative of each zone in the area. As described above, each node (smart meter) in the zone acquires information on the excess or deficiency of power in all the smart meters in the zone, and the representative node collects the power supply and demand information in the zone that aggregates them. Notify the area broker in that area. Based on the electricity supply and demand information aggregated within each zone, the area broker grasps the excess and deficiency of the zone power within the area to be managed, and exchanges power between zones, thereby enabling wide-area power consumption. Optimize usage. In addition, the area broker takes into consideration the difference in characteristics of each power supply source and power consumption source, such as the presence or absence of environmental load and environmental fluctuations, time constraints, and retention time (hereinafter referred to as “power QoS”). By using the smart meter in each home, optimization using scheduling in the time axis direction is performed. This makes it possible to perform optimization in consideration of power QoS.

A description will be given of correction of variations in power consumption due to power interchange within an area with reference to FIG.
In the example shown in FIG. 7, an area 20 having five zones, zone A to zone E, is described, and an area in which power supply and demand information collected by representative nodes of each zone within each zone manages this area. The broker 40 is notified. Thereby, the area broker 40 can grasp the excess or deficiency of electric power in the area 20. In the above description, only the representative node of each zone is connected to the area broker. However, a plurality of nodes in each zone may be connected to the area broker 40.

  Here, as shown in FIG. 7, Zone A, Zone B, and Zone E can supply 35 kWh, 10 kWh, and 35 kWh, respectively, Zone C has a power demand of ± 0 kWh, and Zone D Assume that 80kWh of power is required. In this case, the total amount of power that can be supplied from Zone A, Zone B, and Zone E is 80 kWh, and the amount of power required in Zone D is 80 kWh. It decides to exchange power from the zone E to the zone D, and transmits an instruction corresponding to each target zone. As a result, it is possible to correct power consumption variation between zones in the area 20 and to allow power to be accommodated within the area.

Next, power reservation processing by the area broker will be described. With this process, it is possible to optimize the power consumption in the time axis direction.
FIG. 8 is a diagram illustrating a configuration example of the area broker 40.
As shown in FIG. 8, the area broker 40 includes a control unit 41 that performs various processes such as a process for determining power distribution in the area and a power reservation process, and each of zone A, zone B,. A signal receiving unit 42 that exchanges signals with the zone, a time schedule table 43 that records schedule information of power demand in each zone, and an energy QoS table 44 that indicates the nature of the power supplied from the power supply source for each zone are provided. ing.
The power supply / demand information of each zone notified from the zone A to the zone E includes information such as time constraint conditions that require power and the nature of the power supply source (power QoS). The control unit 41 creates a time schedule table 43 and an energy QoS table 44 based on the power supply / demand information notified from each zone.

FIG. 9 is a diagram illustrating an example of the time schedule table 43. The example shown in this figure shows that zone E requires 5 kWh of power at 1 pm, zone A requires 10 kWh of power at 2 pm, and zone B requires 40 kWh of power at 3 pm.
As described above, the time schedule table 43 records information on the power required in each zone for each time.

FIG. 10 is a diagram illustrating an example of the energy QoS table 44.
The energy QoS table 44 of this example records the amount of power that can be supplied from each zone for each zone, classified into three categories of power QoS. In the example shown in the figure, Zone A has a capacity of 10 kWh for Category 1 (solar light, clean energy, etc.), 30 kWh for Category 2 (storage batteries, etc.), and Category 3 (CO ₂ emissions such as private power generation). It is shown that the amount that can be supplied is 170 kWh. Similarly, the amount of power that can be supplied for other zones is recorded by category. Here, an example is shown in which the power QoS is classified into three categories, but the present invention is not limited to this, and the power QoS can be classified into an arbitrary number of categories.

The control unit 41 of the area broker 40 determines power distribution using the time schedule table 43 and the energy QoS table 44. Then, a power reservation is made based on the determined distribution.
As a power reservation method by the area broker, a centralized management type in which the area broker individually instructs reservations to each node (smart meter) in the area, or the amount of power that the area broker allocates to the zone to the zone Any of the distributed management types in which the individual reservation amount to each smart meter is determined autonomously and distributed based on the amount of power instructed to the area broker in each zone.

FIG. 11 is a diagram illustrating an example of an algorithm for determining power distribution in an area broker.
First, the control unit 41 selects the first zone (in this case, zone A) (S11), and acquires the required power amount from the time schedule table 43 (S12).
Then, by using the category 1 suppliable amount, it is determined whether or not the amount of power required by the zone is satisfied (S13). To proceed to the next zone.
When the required amount of electricity in the category 1 suppliable amount of the zone is insufficient (S13 is insufficient), is the required amount of electricity satisfied by using the categorical available amount of category 2 in the zone? It is determined whether or not (S14). As a result, when the required amount of power is satisfied, it is decided to use the supplied power of category 1 and category 2, and the process proceeds to the next zone.

When the required power amount is insufficient due to the categorical suppliable amount and categorical suppliable amount of the zone (S14 is insufficient), the energy QoS table of the adjacent zone is referred to (S15). And the process of said step S13, S14, and S15 is performed about the information currently recorded on the energy QoS table of this adjacent zone. That is, when the adjacent zone can supply category 1 or category 2 power, the category 1 or category 2 power of the adjacent zone is used. Then, when there are no more adjacent zones to be referred to, the process proceeds to step S16, and it is determined whether or not the necessary power amount is satisfied by using the supplyable amount of category 3 of the own zone. As a result, if satisfied, the process proceeds to the next zone, and if insufficient, the power reservation is not allowed.
As described above, in this embodiment, the power reservation is performed so as not to use category 3 power as much as possible.

FIG. 12 is a diagram illustrating another example of the power reservation algorithm.
This example shows an example of how to use the power QoS category when there is a deadline that uses power. For example, suppose that it is sufficient to dry by the next morning like a dryer. As shown in FIG. 12, when 30 kWh of power is required by the time t, the energy QoS is used in the time zone (best effort time in the figure) where there is a relatively sufficient margin until the time t of the deadline. If a power supply source to be used is searched from among the category 1 or category 2 power sources in the table 44 and approaches the deadline before the power supply source can be determined (when the priority time in the figure is reached), category 3 Search for power supply sources.
Thus, in this example, category 1 or 2 is preferentially used by changing the category to be searched according to the time until the deadline.

Next, a preferred embodiment when there are a plurality of power distribution companies will be described with reference to FIGS. FIG. 13 is a diagram showing an example of an actual power network according to this embodiment, FIG. 14 is a diagram for explaining a virtual power network realized in this embodiment, and FIG. 15 is an internal view of a smart meter 90 in this embodiment. It is a figure which shows an example of a structure.
As shown in FIG. 13, in an actual power network, smart meters of a plurality of users who have contracts with different distribution companies are connected to the same power transmission network 80. Here, A-1, A-2, A-3, and A-4 are contracted with a smart meter of a user of a power distribution company called Company A, and B-1, B-2, and B-3 are contracted with a power distribution company called Company B. C-1 and C-2 are smart meters of users who have contracted with a power distribution company called Company C. Thus, in this embodiment, one power transmission network 80 is shared, but A, B, and C3 companies can share and use them.

  As shown in FIG. 15, the smart meter 90 in this embodiment is provided with a filter 94 and a distribution company designating unit 95 in addition to the control unit 91, the usage status processing unit 92, and the communication unit 93 described above. The power distribution company designating unit 95 is a means for designating a power distribution company with which the user of the power consumption source or power supply source provided with the smart meter 90 is contracted. specify. In the illustrated example, Company A is designated. The filter 94 passes only packets from smart meters (nodes) (A-1 to A-4 in this example) that are contracted with the power distribution company designated by the power distribution company designating unit 95. In order to perform such an operation, for example, each node adds data indicating a contracted power distribution company to a packet to be transmitted, and the filter 94 determines data indicating the power distribution company and transmits the packet. To determine whether or not to pass.

  As a result, the flooded power supply and demand information packet is transmitted only between nodes that specify the same distribution company, and matching processing is performed only between nodes that specify the same distribution company. When the distribution company A is designated as in FIG. 15, the smart meter 90 performs matching of power supply and demand information from A-1 to A-4 selected by the filter 94.

As a result, as shown in FIG. 14, the virtual power network 81 in which the nodes A-1 to A-4 of the user of A company are connected to the same power transmission network 80, and the nodes B-1 to B of the user of B company are connected. A virtual power network 82 to which B-3 is connected and a virtual power network 83 to which users C-1 and C-2 of company C are connected are constructed.
In this way, the A company to the C company can balance power supply and power sale independently, so that a total balance can be achieved.
Also, as shown in FIG. 15, when a distribution company is specified, a control packet of only that power company is received as a virtual network. Therefore, by changing the specification of the distribution company specifying unit 95, the power from any distribution company can be changed. You will also be purchasing.

  1: power consumption source or power supply source such as home or office, 2: smart meter, 3: power transmission network, 4: control network, 10: power network, 20-24: area, 30-34: zone, 40: area broker , 41: control unit, 42: signal receiving unit, 43: time schedule table, 44: energy QoS table, 51-57: node (smart meter), 60, 61, 63: power supply / demand information packet, 62, 64: Response packet, 70: smart meter, 71: control unit, 72: usage status processing unit, 73: communication unit, 80: power transmission network, 81-83: virtual power network, 90: smart meter, 91: control unit, 92: use Situation processing part, 93: Communication part, 94: Filter, 95: Distribution company designation part

Claims (4)

A smart meter installed in each of the power consumption source or the power supply source and connected to the power transmission network and the control network, the function of controlling power supply and demand between the power consumption source or the power supply source and the power transmission network The power supply / demand information, which is information indicating the amount of power necessary or available for the power consumption source or power supply source, is output to the control network and advertised to other smart meters, and the other smart received A smart meter having a function of responding to the power supply and demand information of the meter based on its own power supply and demand information;
A control network connected to the plurality of smart meters and transferring the power supply and demand information output from each smart meter;
The smart meter controls power supply / demand in a power consumption source or a power supply source in which the smart meter is installed based on power supply / demand information received from the control network.   The control network is divided into a plurality of first areas, and power distribution in the first area is controlled by a server provided for each first area, and the first area is further divided into a plurality of areas. 2. The power network control network according to claim 1, wherein the power distribution is divided into second areas, and power distribution in the second area is distributedly controlled by the smart meter performing flooding advertisement of the power supply and demand information.   The power network control network according to claim 2, wherein the power distribution is determined based on a power consumption amount, a suppliable power amount, and a property of each power consumption source or power supply source.   The smart meter includes a power distribution company designating unit and means for receiving only power supply and demand information from a user of the power distribution company set by the power distribution company designating unit, and the virtual meter is virtually divided for each power distribution company. The power network control network according to claim 1, wherein a control network is realized.

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