JP2011193625A - Power controller, power control system, storage battery controlling method, and program - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To increase an amount of power that is used in a distribution network out of power transmitted from each base to the distribution network. <P>SOLUTION: A power controller 100 obtains base identifying information of a base that uses power, from a control unit 310 of any one of bases. The power controller 100 determines a battery 300 that is to distribute power to a distribution network 10, using the obtained base identifying information, memorized supply loss information, and memorized transmission loss information. The power controller 100 then controls the control unit 310 corresponding to the battery 300 that is to distribute power to the distribution network 10 and causes the battery 300 to supply power to the distribution network 10. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a power control apparatus, a power control system, a storage battery control method, and a program for controlling a storage battery installed at a site that uses power.

  Increasingly, power generation devices using renewable energy, such as solar cell power generation devices, are introduced into each home. The amount of power generated by a power generator using renewable energy varies depending on the weather and is difficult to match the amount used at home. For this reason, such a power generator is equipped with a storage battery. When the amount of charge of the storage battery reaches 100%, the power generated by the power generation device is often purchased by a business operator that conducts a power business in the form of transmitting power to a public distribution network (see, for example, Patent Document 1).

  On the other hand, Patent Document 2 discloses a power distribution automation system that manages a power distribution network. This power distribution automation system performs power interchange calculation in the event of a power failure.

JP 2003-122819 A JP 2008-61334 A

  The power supply network is composed of a power transmission network that transmits power from a power plant and a plurality of distribution networks that distribute the power transmitted through the power transmission network to each base. When power flows back from the distribution network to the power transmission network, the amount of power to flow back is unstable, so the voltage of the power transmission network becomes unstable. Moreover, since the voltage is different between the transmission network and the distribution network, a power loss occurs between the transmission network and the distribution network. For these reasons, it is desirable that the power flowing between the power transmission network and the distribution network be as small as possible.

  On the other hand, as described above, in recent years, an increasing number of households and businesses have installed power generation devices using renewable energy. For this reason, a plurality of unstable power supply sources are connected to the distribution network. In order to efficiently use the power generated at each base, it is necessary to reduce the power flowing between the power distribution network and the power transmission network as much as possible and to reduce the loss in the power distribution network.

  An object of the present invention is to provide a power control device, a power control system, a storage battery control method, and a program that can efficiently use the power generated at each site.

According to the present invention, a plurality of locations that are located in different locations and use power,
A storage battery installed in at least one of the plurality of bases;
A power distribution network connecting the plurality of bases;
A power control device for controlling a power distribution system having
Request information acquisition means for receiving power consumption information indicating that the power of the distribution network is consumed from any of the bases;
When the request information acquisition means receives the power consumption information, a storage battery determination means for discharging any of the storage batteries to the distribution network;
A power control apparatus is provided.

According to the present invention, a plurality of locations that are located in different locations and use power,
A storage battery installed in at least one of the plurality of bases;
A power generator installed in at least one of the plurality of bases;
A power distribution network connecting the plurality of bases;
A power control device for controlling a power distribution system having
Request information acquisition means for receiving power supply information indicating that surplus power is supplied to the distribution network from any of the bases;
When the request information acquisition means receives the power supply information, storage battery determination means for storing the power of the distribution network in any of the storage batteries;
A power control apparatus is provided.

According to the present invention, a plurality of locations that are located in different locations and use power,
A storage battery installed in at least one of the plurality of bases;
A power distribution network connecting the plurality of bases;
A power control system for controlling a power distribution system comprising:
Battery control means provided in each of the storage batteries to control charging / discharging of the storage battery;
A power control device that controls charging / discharging of all the storage batteries via all the battery control means;
With
The power control device
Request information acquisition means for receiving power consumption information indicating that the power of the distribution network is consumed from any of the bases;
A storage battery determination means for controlling the battery control means of any of the storage batteries to cause the storage battery to discharge to the distribution network when the request information acquisition means receives the power consumption information;
A power control system is provided.

According to the present invention, a plurality of locations that are located in different locations and use power,
A storage battery installed in at least one of the plurality of bases;
A power generator installed in at least one of the plurality of bases;
A power distribution network connecting the plurality of bases;
A power control system for controlling a power distribution system comprising:
The plurality of bases are preliminarily given different base identification information,
Battery control means provided in each of the storage batteries to control charging / discharging of the storage battery;
A power control device that controls charging / discharging of all the storage batteries via all the battery control means;
With
The power control device
Request information acquisition means for receiving power supply information indicating that surplus power is supplied to the distribution network from any of the bases;
When the request information acquisition unit receives the power supply information, a storage battery determination unit that controls the battery control unit of any of the storage batteries and causes the storage battery to store the power of the distribution network;
A power control system is provided.

According to the present invention, a plurality of locations that are located in different locations and use power,
A storage battery installed in at least one of the plurality of bases;
A power distribution network connecting the plurality of bases;
A battery control method for controlling the storage battery,
Base identification information for identifying the base from other bases is given in advance to the plurality of bases,
Provided is a storage battery control method for discharging any of the storage batteries to the distribution network when the computer receives power consumption information indicating that the power of the distribution network is consumed from any of the bases. .

According to the present invention, a plurality of locations that are located in different locations and use power,
A storage battery installed in at least one of the plurality of bases;
A power generator installed in at least one of the plurality of bases;
A power distribution network connecting the plurality of bases;
A battery control method for controlling the storage battery,
Provided is a storage battery control method for storing power of the distribution network in any of the storage batteries when a computer receives power supply information indicating that surplus power is supplied to the distribution network from any of the bases. The

According to the present invention, a program for causing a computer to function as a power control device that controls a storage battery provided in a power distribution system,
The power distribution system
It is located in different places and has multiple locations that use electricity,
A storage battery installed in at least one of the plurality of bases;
A power distribution network connecting the plurality of bases;
Have
In the computer,
A function of receiving power consumption information indicating that the power of the distribution network is consumed from any of the bases;
A function of discharging any of the storage batteries to the power distribution network when receiving the power consumption information;
A program for realizing the above is provided.

According to the present invention, a program for causing a computer to function as a power control device that controls a storage battery provided in a power distribution system,
The power distribution system
It is located in different places and has multiple locations that use electricity,
A storage battery installed in at least one of the plurality of bases;
A power generator installed in at least one of the plurality of bases;
A power distribution network connecting the plurality of bases;
Have
In the computer,
A function of receiving power supply information indicating that surplus power is supplied to the distribution network from any of the bases;
When the power supply information is received, a function of storing power of the distribution network in any of the storage batteries;
A program for realizing the above is provided.

  ADVANTAGE OF THE INVENTION According to this invention, the electric energy used in the distribution network among the electric power transmitted to a distribution network from each base can be increased.

It is a figure which shows the structure of the electric power control system which concerns on 1st Embodiment. It is a block diagram which shows the function structure of an electric power control apparatus. It is a figure for demonstrating the information which the supply loss memory | storage part memorize | stores, and the information which the power transmission loss memory | storage part has memorize | stored. It is a figure which shows the information which the supply loss memory | storage part has memorize | stored in a table format. It is a figure which shows the information which the power transmission loss memory | storage part has memorize | stored in a table format. 3 is a flowchart showing a first operation of the power control apparatus shown in FIG. 2. 3 is a flowchart showing a second operation of the power control apparatus shown in FIG. 2. It is a block diagram which shows the function structure of the power control apparatus which concerns on 2nd Embodiment. It is a figure which shows the information which the battery information storage part has memorize | stored in a table format. It is a flowchart which shows the 1st operation | movement of the electric power control apparatus shown in FIG. It is a flowchart which shows the 2nd operation | movement of the electric power control apparatus shown in FIG.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. In all the drawings, the same reference numerals are given to the same components, and the description will be omitted as appropriate.

(First embodiment)
FIG. 1 is a diagram illustrating a configuration of a power control system according to the first embodiment. This power control system is a system for controlling a power distribution system. The power distribution system includes a plurality of bases, a storage battery 300 installed in at least one of the plurality of bases, and a power distribution network 10 connecting the plurality of bases. Electric power is used at each site. The current flowing through the distribution network 10 is unidirectional. The power control system includes a control unit 310 and a power control device 100 provided in each storage battery 300. The control unit 310 controls charging / discharging of the storage battery 300 and performs processing for transmitting power to the distribution network 10 by the storage battery 300. The power control apparatus 100 controls charging / discharging of all the storage batteries 300 via all the control units 310.

  Specifically, an electrical device 400 is installed at a site that uses power. At least one of the bases is provided with a solar power generation device 200 as a power generation device using renewable energy. The electric power generated by the solar power generation apparatus 200 is used by the electric device 400 via the storage battery 300 or directly by the electric device 400. When the remaining capacity of the storage battery 300 becomes zero, the insufficient power is supplied to the electric device 400 via the power distribution network 10.

  The storage battery 300 stores the electric power generated by the solar power generation device 200. The electric power stored in the storage battery 300 is used by the electrical equipment 400 at the site where the storage battery 300 is installed, and is also supplied to the power distribution network 10. The power control apparatus 100 controls the timing at which the storage battery 300 supplies power to the power distribution network 10.

  In addition, the control unit 310 transmits power consumption information to the power control apparatus 100 when the use of the electric device 400 is started and the storage amount of the storage battery 300 becomes zero.

  FIG. 2 is a block diagram illustrating a functional configuration of the power control apparatus 100. Base identification information for identifying the base from other bases is given in advance to the plurality of bases. The power control apparatus 100 includes a supply loss storage unit 110, a power transmission loss storage unit 120, a request information acquisition unit 130, and a storage battery determination unit 140.

  The supply loss storage unit 110 stores supply loss information in association with the base identification information of the base where the storage battery 300 is located, for each storage battery 300. The supply loss information is information indicating a ratio of power loss from the storage battery 300 to the power distribution network 10. The power transmission loss storage unit 120 stores power transmission loss information in association with the base identification information for each base. The power transmission loss information is information indicating a ratio of power transmission loss in the power distribution network 10 with a base located next to the base.

  The request information acquisition unit 130 acquires the base identification information of a base that uses power from the control unit 310 of any base. The storage battery determination unit 140 uses the base identification information acquired by the request information acquisition unit 130, the supply loss information stored in the supply loss storage unit 110, and the transmission loss information stored in the power transmission loss storage unit 120. The storage battery 300 that should supply power to the power distribution network 10 is determined. Then, the storage battery determination unit 140 controls the control unit 310 corresponding to the storage battery 300 that is to supply power to the distribution network 10, and supplies power from the storage battery 300 to the distribution network 10.

  In FIG. 2, each component of the power control apparatus 100 is not a hardware unit configuration but a functional unit block. Each component of the power control apparatus 100 is centered on an arbitrary computer CPU, memory, a program that realizes the components shown in FIG. It is realized by any combination of hardware and software.

  FIG. 3 is a diagram for explaining the information stored in the supply loss storage unit 110 and the information stored in the power transmission loss storage unit 120. When power flows through the wiring, power loss occurs due to wiring resistance or the like. In addition, power loss occurs when power is transmitted from the storage battery 300 to the power distribution network 10.

  Specifically, when power is transmitted from the storage battery 300 to the distribution network 10, it is caused by a loss when discharging from the storage battery 300 (storage battery loss ratio: for example, 6% at the base A) and a conversion loss when converting direct current to alternating current. Loss (conversion rate loss: for example, 4% at site A). The supply loss storage unit 110 stores information indicating these.

  In the power distribution network 10, there is a loss due to the resistance of the distribution line (for example, 3% between the base A and the base B). The power transmission loss storage unit 120 stores information indicating the loss ratio.

  FIG. 4 is a diagram illustrating information stored in the supply loss storage unit 110 in a table format. As shown in the figure, the supply loss storage unit 110 stores a power loss ratio, that is, supply loss information when the storage battery 300 provided at the base supplies power to the distribution network 10 for each base. In the example shown in the figure, the supply loss information is divided into a storage battery loss ratio and a conversion loss ratio and stored in association with the base identification information. When a plurality of storage batteries 300 are provided at one base, at least the storage battery loss ratio is stored for each base by storage battery identification information. In general, since one DC / AC converter is provided at one site, one conversion loss ratio may be stored for each site. However, this does not apply when a plurality of DC / AC converters are provided at one site.

  FIG. 5 is a diagram illustrating information stored in the power transmission loss storage unit 120 in a table format. As shown in the figure, the power transmission loss storage unit 120 uses, as power transmission loss information, the power loss ratio by the power distribution network 10 between the first base and the second base adjacent to the first base. The base identification information of the first base and the base identification information of the second base are stored in association with each other. By combining these power loss ratios, the storage battery determination unit 140 can calculate the power loss ratio in the distribution network 10 between any bases. At this time, the storage battery determination unit 140 determines a portion of the distribution network 10 located between the bases in a direction along the direction of current in the distribution network 10, and calculates a power loss ratio in the determined portion.

  FIG. 6 is a flowchart showing a first operation of the power control apparatus 100. First, when the use of the electric device 400 is started at any of the bases, the power consumed by the electric device 400 is first supplied from the storage battery 300 in the base. When the storage amount of the storage battery 300 becomes zero, the power consumed by the electric device 400 is supplied from the power distribution network 10. And the control part 310 of the base transmits the power consumption information which shows that the electrical storage amount of the storage battery 300 becomes 0, and the use of the electric equipment 400 is continuing to the electric power control apparatus 100. The power consumption information includes the base identification information of the base.

  The request information acquisition unit 130 of the power control apparatus 100 receives the power consumption information (step S10). Next, the storage battery determination unit 140 reads each supply loss information from the supply loss storage unit 110 (step S20). At this time, the storage battery determination unit 140 may not read the supply loss information corresponding to the base identification information included in the power consumption information received by the request information acquisition unit 130.

  Moreover, the storage battery determination part 140 reads each power transmission loss information from the power transmission loss memory | storage part 120 (step S30).

  Then, the storage battery determination unit 140 calculates the power loss ratio between the storage battery 300 and the base indicated by the base identification information received in step S10 for each storage battery 300 using the supply loss information and the transmission loss information ( Step S40). In this process, the storage battery 300 located at the site indicated in the site identification information received in step S10 is excluded from the processing target.

  Next, the storage battery determination unit 140 determines the storage battery 300 having the smallest power loss ratio calculated in step S40 as the storage battery 300 to be discharged to the distribution network 10 (step S50). Next, the storage battery determination unit 140 controls the control unit 310 corresponding to the storage battery 300 determined in step S50 to supply power from the storage battery 300 to the distribution network 10 (step S60).

  Here, the processing shown in steps S40 and S50 will be specifically described with reference to the diagram shown in FIG. Consider a case where the amount of power stored in the storage battery 300 at the site A becomes zero. In this case, power is supplied to the power distribution network 10 from either the storage battery 300 at the base C or the storage battery 300 at the base D.

  The power loss ratio in the power distribution network 10 from the base C to the base A is 2%, and the power loss ratio from the storage battery 300 in the base C to the power distribution network 10 is 10 + 7 = 17%. For this reason, when the storage battery 300 at the site C is discharged, the power loss ratio is 2 + 17 = 19%.

  On the other hand, the power loss ratio in the power distribution network 10 from the base D to the base A is 2 + 3 = 5%, and the power loss ratio from the storage battery 300 in the base D to the power distribution network 10 is 6 + 4 = 10%. For this reason, when the storage battery 300 at the site D is discharged, the power loss ratio is 5 + 10 = 15%. This value is smaller than the power loss ratio (19%) when the storage battery 300 at the base C discharges. Therefore, the storage battery determination unit 140 determines the storage battery 300 at the site D as the storage battery 300 to be discharged.

  FIG. 7 is a flowchart showing a second operation of the power control apparatus 100. The processing shown in the figure is performed when the storage battery storage ratio is 100% at a certain base, and the power generated by the solar power generation device 200 is supplied to the distribution network 10 as surplus power. When the power generated by the solar power generation apparatus 200 starts to be supplied to the distribution network 10 as surplus power, the control unit 310 at that site transmits power supply information indicating that fact to the power control apparatus 100. The power supply information includes base identification information of the base.

  The request information acquisition unit 130 of the power control apparatus 100 receives the power supply information (step S110). Next, the storage battery determination unit 140 reads each supply loss information from the supply loss storage unit 110 (step S120). At this time, the storage battery determination unit 140 may not read the supply loss information corresponding to the base identification information included in the power supply information received by the request information acquisition unit 130.

  Moreover, the storage battery determination part 140 reads each power transmission loss information from the power transmission loss memory | storage part 120 (step S130).

  Then, the storage battery determination unit 140 calculates the power loss ratio between the storage battery 300 and the base indicated by the base identification information received in step S110 for each storage battery 300 using the supply loss information and the transmission loss information ( Step S140). In this process, the storage battery 300 located at the base indicated by the base identification information included in the power supply information received by the request information acquisition unit 130 is excluded from the processing target.

  Next, the storage battery determination unit 140 determines the storage battery 300 having the smallest power loss ratio calculated in step S140 as the storage battery 300 that should store the power of the distribution network 10 (step S150). Next, the storage battery determination unit 140 controls the control unit 310 corresponding to the storage battery 300 determined in step S150, and causes the storage battery 300 to store the power of the distribution network 10 (step S160).

  Here, the processing shown in steps S140 and S150 will be specifically described with reference to the diagram shown in FIG. Consider a case where the amount of power stored in the storage battery 300 at the site A reaches 100%. In this case, one of the storage battery 300 at the base C and the storage battery 300 at the base D stores the power of the power distribution network 10.

  The power loss ratio in the power distribution network 10 from the base C to the base A is 2%, and the power loss ratio from the storage battery 300 in the base C to the power distribution network 10 is 10 + 7 = 17%. For this reason, when the storage battery 300 at the site C is charged, the power loss ratio is 2 + 17 = 19%.

  On the other hand, the power loss ratio in the power distribution network 10 from the base D to the base A is 2 + 3 = 5%, and the power loss ratio from the storage battery 300 in the base D to the power distribution network 10 is 6 + 4 = 10%. For this reason, when the storage battery 300 at the site D is charged, the power loss ratio is 5 + 10 = 15%. This value is smaller than the power loss ratio (19%) when the storage battery 300 at the site C is charged. Therefore, the storage battery determination unit 140 determines the storage battery 300 at the site D as the storage battery 300 to be charged.

  Next, the operation and effect of this embodiment will be described. According to this embodiment, when power from the power distribution network 10 is consumed at a certain base, power is supplied to the power distribution network 10 from the storage battery 300 belonging to the same power distribution network 10. That is, instead of supplying power from the power transmission network to the distribution network 10, power is supplied from the storage battery 300 located in the distribution network 10. Therefore, among the electric power transmitted from each base to the power distribution network 10, the amount of power used in the power distribution network 10 can be increased.

  At this time, the power control apparatus 100 selects the storage battery 300 that should supply power to the distribution network 10 so that the power loss is minimized. Therefore, the loss amount of the electric power generated inside the power distribution network 10 can be reduced.

  Therefore, the electric power generated at each base can be used efficiently.

  When surplus power is supplied to the power distribution network 10 at a certain base, the power control apparatus 100 stores power in the storage battery 300 located in the power distribution network 10. Therefore, it is possible to reduce the amount of power that is sent back from the power distribution network 10 to the power transmission network. Therefore, the electric power generated at each base can be used efficiently.

  At this time, the power control apparatus 100 selects the storage battery 300 to be charged with the power of the distribution network 10 so that the power loss is minimized. Therefore, the loss amount of the electric power generated inside the power distribution network 10 can be reduced.

(Second Embodiment)
The power supply system according to the second embodiment has the same configuration as that of the power supply system according to the first embodiment except for the functional configuration of the power control apparatus 100.

  FIG. 8 is a block diagram illustrating a functional configuration of the power control apparatus 100 according to the present embodiment. This power control apparatus 100 is the first implementation except that each storage battery 300 is preliminarily provided with storage battery identification information to be identified from another storage battery 300 and has a battery information storage unit 150. It is the structure similar to the power control apparatus 100 which concerns on a form. In the present embodiment, the site identification information also serves as the storage battery identification information.

  The battery information storage unit 150 stores battery information indicating the state of the storage battery in association with the storage battery identification information for each storage battery. In addition to the supply loss information stored in the supply loss storage unit 110 and the transmission loss information stored in the power transmission loss storage unit 120, the storage battery determination unit 140 further uses the battery information to supply power to the distribution network 10. The storage battery 300 to be supplied is determined.

  FIG. 9 is a diagram showing information stored in the battery information storage unit 150 in a table format. The battery information storage unit 150 stores the number of times of charging / discharging and the current charging rate as battery information.

  A storage battery generally deteriorates as the number of charge / discharge cycles increases. In addition, if charging is repeatedly performed without using all of the stored power, the discharge voltage suddenly decreases in the vicinity of the remaining amount where the additional charging is started, and as a result, the remaining capacity of the storage battery decreases. May be visible. Therefore, the storage battery determination unit 140 determines the storage battery 300 that should supply power to the power distribution network 10 using the number of times of charging / discharging and the current charging rate. Specific processing will be described later using a flowchart.

  FIG. 10 is a flowchart showing a first operation of power control apparatus 100 shown in FIG. This figure corresponds to FIG. 6 in the first embodiment. The processing shown in this figure is the same as the processing described with reference to FIG. 6 up to step S40, and thus description thereof is omitted.

  In step S40, storage battery determination unit 140 calculates a power loss ratio between storage battery 300 and the base indicated in the base identification information received in step S10 for each storage battery 300. Next, the storage battery determination unit 140 reads each piece of battery information from the battery information storage unit 150 (step S42).

Then the storage battery determination unit 140 calculates the index _{S 1} using the following equation (1) (step S44).
Index S ₁ = (power loss ratio (%) calculated in step S40) + α × number of times of charging / discharging + β / remaining capacity (1)
Where α is a constant and β is a constant.

Then the storage battery determination unit 140, the smallest battery 300 index _{S 1,} defined as the storage battery 300 to be discharged to the grid 10 (step S50). Next, the storage battery determination unit 140 controls the control unit 310 corresponding to the storage battery 300 determined in step S50 to supply power from the storage battery 300 to the distribution network 10 (step S60).

  FIG. 11 is a flowchart showing a second operation of power control apparatus 100 shown in FIG. This figure corresponds to FIG. 7 in the first embodiment. The processing shown in this figure is the same as the processing described with reference to FIG. 6 up to step S140, and thus description thereof is omitted.

  In step S140, storage battery determination unit 140 calculates a power loss ratio between storage battery 300 and the base indicated in the base identification information received in step S110 for each storage battery 300. Next, the storage battery determination unit 140 reads each piece of battery information from the battery information storage unit 150 (step S142).

Then the storage battery determination unit 140 calculates the index _{S 2} using the following equation (2) (step S144).
Index S ₂ = (power loss ratio (%) calculated in step S140) + γ × number of times of charging / discharging + θ × remaining capacity (1)
Where γ is a constant and θ is a constant. Note that γ may be the same value as α in Equation (1).

Then the storage battery determination unit 140, the smallest battery 300 index _{S 2,} defined as the storage battery 300 to be a power storage from the power distribution network 10 (step S150). Next, the storage battery determination unit 140 controls the control unit 310 corresponding to the storage battery 300 determined in step S150, and causes the storage battery 300 to store the power of the distribution network 10 (step S160).

  Also according to this embodiment, the same effect as that of the first embodiment can be obtained. Moreover, since the storage battery 300 is selected using battery information such as the number of charge / discharge cycles and the remaining capacity, it is possible to suppress the concentration of charge / discharge on the specific storage battery 300.

  In each of the above-described embodiments, for example, the following control is possible.

  In the example illustrated in FIG. 3, it is assumed that the use of the electric device 400 at the site C is started. At this time, the power loss ratio from the storage battery 300 of all bases to the electrical equipment 400 of the base C is calculated. For example, the power loss ratio from the storage battery 300 at the site C to the electrical device 400 at the site C is 10 + 7 = 17%. On the other hand, the power loss ratio from the storage battery 300 at the site A to the electrical device 400 at the site C is 6 + 4 + 1 + 1 + 3 = 15%. Further, the power loss ratio from the storage battery 300 at the site D to the electrical device 400 at the site C is 6 + 4 + 3 = 13%. For this reason, rather than using the power of the storage battery 300 of the same base C, the power loss ratio is lower when the power of the storage battery 300 of another base, for example, the base D is used. In this case, the electric device 400 at the site C is supplied with power from the power distribution network 10, and the storage battery 300 at the site D is discharged to the power distribution network 10.

  As mentioned above, although embodiment of this invention was described with reference to drawings, these are the illustrations of this invention, Various structures other than the above are also employable.

For example, in each of the above-described embodiments, the power control apparatus 100 calculates the power loss ratio and S ₁ and S _2. However, the control unit 310 at each site determines the power loss ratio and the distribution network of S ₁ and S ₂ Information other than the loss ratio by 10 may be periodically calculated and transmitted to the power control apparatus 100.

In addition, it can be said that the power loss ratio used as the determination index in the first embodiment indicates the cost when the two storage batteries 300 are linked via the power distribution network 10, that is, the link cost. In addition, it can be said that the index S2 in the _second embodiment also indicates the link cost. That is, in each of the above-described embodiments, the combination of the two storage batteries 300 is selected so that the cost when the two storage batteries 300 are linked via the power distribution network 10 is minimized. Here, the link cost is not limited to the above example. For example, another term may be added to the power loss ratio in the first embodiment and the expression (2) in the second embodiment as necessary. As another term added here, for example, the price at which an electric power company purchases electric power from a base, the performance and frequency of use of each device, and the like can be cited.

DESCRIPTION OF SYMBOLS 10 Distribution network 100 Power control apparatus 110 Supply loss memory | storage part 120 Transmission loss memory | storage part 130 Request information acquisition part 140 Storage battery determination part 150 Battery information storage part 200 Solar power generation device 300 Storage battery 310 Control part 400 Electric equipment

Claims (15)

It is located in different places and has multiple locations that use electricity,
A storage battery installed in at least one of the plurality of bases;
A power distribution network connecting the plurality of bases;
A power control device for controlling a power distribution system having
Request information acquisition means for receiving power consumption information indicating that the power of the distribution network is consumed from any of the bases;
When the request information acquisition means receives the power consumption information, a storage battery determination means for discharging any of the storage batteries to the distribution network;
A power control apparatus comprising: The power control apparatus according to claim 1,
Base identification information for identifying the base from other bases is given in advance to the plurality of bases,
Supply loss storage means for storing supply loss information indicating a ratio of power loss from the storage battery to the distribution network in association with the base identification information of the base where the storage battery is located, for each storage battery;
Transmission loss storage means for storing, in association with the base identification information, transmission loss information indicating the ratio of power transmission loss in the distribution network with the other bases for each base,
With
The power consumption information includes the site identification information of the site using power,
The storage battery determination means includes the base identification information acquired by the request information acquisition means, the supply loss information stored in the supply loss storage means, and the transmission loss information stored in the transmission loss storage means. A storage battery determining means for determining the storage battery to supply power to the distribution network;
A power control apparatus comprising: The power control apparatus according to claim 1 or 2,
Provided in each of the storage batteries, further comprising battery control means for controlling the discharge from the storage battery to the distribution network;
The storage battery determination unit controls the battery control unit of the storage battery to supply power to the distribution network, and supplies power from the storage battery to the distribution network. In the electric power control apparatus as described in any one of Claims 1-3,
Battery information storage means for storing battery information indicating the state of the storage battery for each storage battery,
The storage battery determining means further determines the storage battery to be supplied with power to the distribution network using the battery information. The power control apparatus according to claim 4,
The battery information is a power control device including a charge / discharge count. In the electric power control apparatus according to claim 4 or 5,
The battery control information includes a charge ratio. It is located in different places and has multiple locations that use electricity,
A storage battery installed in at least one of the plurality of bases;
A power generator installed in at least one of the plurality of bases;
A power distribution network connecting the plurality of bases;
A power control device for controlling a power distribution system having
Request information acquisition means for receiving power supply information indicating that surplus power is supplied to the distribution network from any of the bases;
When the request information acquisition means receives the power supply information, storage battery determination means for storing the power of the distribution network in any of the storage batteries;
A power control apparatus comprising: The power control apparatus according to claim 7, wherein
The plurality of bases are preliminarily given different base identification information,
Supply loss storage means for storing supply loss information indicating a ratio of power loss from the storage battery to the distribution network in association with the base identification information of the base where the storage battery is located, for each storage battery;
Transmission loss storage means for storing, in association with the base identification information, transmission loss information indicating the ratio of power transmission loss in the distribution network with the other bases for each base,
With
The power supply information includes the site identification information of the site having the power generation device that supplies surplus power to the distribution network,
The storage battery determination means includes the base identification information acquired by the request information acquisition means, the supply loss information stored in the supply loss storage means, and the transmission loss information stored in the transmission loss storage means. A power control apparatus that uses the storage battery to charge the power of the distribution network. The power control apparatus according to claim 8, wherein
Provided in each of the storage batteries, further comprising battery control means for controlling charging from the power distribution network to the storage battery,
The storage battery determination unit is a power control device that controls the battery control unit of the storage battery to be charged with the power of the distribution network, and causes the storage battery to charge the power of the distribution network. It is located in different places and has multiple locations that use electricity,
A storage battery installed in at least one of the plurality of bases;
A power distribution network connecting the plurality of bases;
A power control system for controlling a power distribution system comprising:
Battery control means provided in each of the storage batteries to control charging / discharging of the storage battery;
A power control device that controls charging / discharging of all the storage batteries via all the battery control means;
With
The power control device
Request information acquisition means for receiving power consumption information indicating that the power of the distribution network is consumed from any of the bases;
A storage battery determination means for controlling the battery control means of any of the storage batteries to cause the storage battery to discharge to the distribution network when the request information acquisition means receives the power consumption information;
A power control system comprising: It is located in different places and has multiple locations that use electricity,
A storage battery installed in at least one of the plurality of bases;
A power generator installed in at least one of the plurality of bases;
A power distribution network connecting the plurality of bases;
A power control system for controlling a power distribution system comprising:
The plurality of bases are preliminarily given different base identification information,
Battery control means provided in each of the storage batteries to control charging / discharging of the storage battery;
A power control device that controls charging / discharging of all the storage batteries via all the battery control means;
With
The power control device
Request information acquisition means for receiving power supply information indicating that surplus power is supplied to the distribution network from any of the bases;
When the request information acquisition unit receives the power supply information, a storage battery determination unit that controls the battery control unit of any of the storage batteries and causes the storage battery to store the power of the distribution network;
A power control system comprising: It is located in different places and has multiple locations that use electricity,
A storage battery installed in at least one of the plurality of bases;
A power distribution network connecting the plurality of bases;
A battery control method for controlling the storage battery,
Base identification information for identifying the base from other bases is given in advance to the plurality of bases,
A storage battery control method for discharging any of the storage batteries to the distribution network when the computer receives power consumption information indicating that the power of the distribution network is consumed from any of the bases. It is located in different places and has multiple locations that use electricity,
A storage battery installed in at least one of the plurality of bases;
A power generator installed in at least one of the plurality of bases;
A power distribution network connecting the plurality of bases;
A battery control method for controlling the storage battery,
A storage battery control method in which, when a computer receives power supply information indicating that surplus power is supplied to the distribution network from any of the bases, the storage battery stores power in the distribution network. A program for causing a computer to function as a power control device for controlling a storage battery provided in a power distribution system,
The power distribution system
It is located in different places and has multiple locations that use electricity,
A storage battery installed in at least one of the plurality of bases;
A power distribution network connecting the plurality of bases;
Have
In the computer,
A function of receiving power consumption information indicating that the power of the distribution network is consumed from any of the bases;
A function of discharging any of the storage batteries to the power distribution network when receiving the power consumption information;
A program that realizes A program for causing a computer to function as a power control device for controlling a storage battery provided in a power distribution system,
The power distribution system
It is located in different places and has multiple locations that use electricity,
A storage battery installed in at least one of the plurality of bases;
A power generator installed in at least one of the plurality of bases;
A power distribution network connecting the plurality of bases;
Have
In the computer,
A function of receiving power supply information indicating that surplus power is supplied to the distribution network from any of the bases;
When the power supply information is received, a function of storing power of the distribution network in any of the storage batteries;
A program that realizes

Images