JP6796402B2 - Power supply system - Google Patents

Description

The present invention relates to a technique of a power supply system including a plurality of storage battery systems capable of charging and discharging electric power.

Conventionally, a technique of a power supply system including a plurality of storage battery systems capable of charging and discharging electric power has been known. For example, as described in Patent Document 1.

The electric power supply system described in Patent Document 1 has a plurality of storage battery systems (battery units) capable of charging and discharging electric power. In such a power supply system, power from a plurality of storage battery systems can be supplied to the load. That is, it is possible to supply the load with an amount of electric power that is difficult to obtain with only one storage battery system.

Japanese Unexamined Patent Publication No. 2016-73009

However, when power is supplied to the load from a plurality of storage battery systems as in the power supply system described in Patent Document 1, the storage battery system connected to the downstream side (load side) is preferentially discharged. As a result, there is a risk that the discharge or charge will be biased toward a specific storage battery system.

The present invention has been made in view of the above situations, and the problem to be solved is power supply capable of preventing the discharge or charge from being biased to a specific storage battery system among a plurality of storage battery systems. It provides a system.

The problem to be solved by the present invention is as described above, and next, the means for solving this problem will be described.

That is, a plurality of power generation systems capable of generating power using natural energy and a plurality of the power generation systems are provided corresponding to each of the power generation systems, and the distribution line connecting the system power supply and the load is directed from the system power supply toward the load side. are connected so arranged, with the power to chargeable and the load power from the power generation system corresponding can be supplied, a plurality of the battery system capable of executing multiple operating modes of the operation, the battery storage system The storage battery system includes a control unit for switching the operation mode, and has a storage battery system sensor that detects power immediately upstream of the connection point between the distribution line and the storage battery system, and also has the operation mode. As a result , it is possible to execute a discharge mode in which the power according to the load request acquired by the detection result of the storage battery system sensor can be discharged at the discretion of the storage battery system , or a stop mode in which the power cannot be discharged. The control unit acquires the remaining battery level of the storage battery system, prioritizes a plurality of the storage battery systems in descending order of the acquired remaining battery level, and discharges the storage battery system having the highest priority. the electric power corresponding to the requirements of the load as a mode to allow discharge by determination of the storage battery system of the uppermost is more storage battery system as to the stop mode.

The distribution line includes a shortage power supply system connected to the system power supply side of the plurality of storage battery systems, and the shortage power supply system is immediately upstream of the connection point between the distribution line and the shortage power supply system. When the power from the storage battery system in the discharge mode is insufficient for the demand of the load, it is acquired by the detection result of the sensor for the insufficient power supply system. the power shortage said to the load subjected feeding the discretion of the missing power supply system is, wherein, when the power to the load from the power shortage supply system is supplied, the discharge mode Among the storage battery systems in the stop mode that do not include the storage battery system having the highest priority, the storage battery system having the highest priority is set to the discharge mode.

The plurality of storage battery systems may be owned by any one of the plurality of consumers, and the insufficient power supply system may be shared by the plurality of consumers.
With such a configuration, it is possible to more effectively prevent the discharge or charge from being biased to a specific storage battery system among the multiple storage battery systems by using a system shared by a plurality of consumers that supplies power to the load. Can be done.

As the effect of the present invention, the following effects are exhibited.

It is possible to prevent the discharge or charge from being biased to a specific storage battery system among the plurality of storage battery systems.

The block diagram which showed the structure of the power supply system which concerns on 1st Embodiment. Similarly, a block diagram showing an example of a power supply mode when the normal mode is executed. Similarly, a flowchart showing the time zone processing by EMS when the equal mode is executed. Similarly, a flowchart showing a preset process by EMS when the equal mode is executed. Similarly, the figure which showed an example of the set discharge priority. Similarly, a flowchart showing the processing of the storage battery system operation according to the first embodiment by the EMS when the equal mode is executed. Similarly, a block diagram showing an example of a power supply mode when the equal mode is executed. Similarly, a flowchart showing the processing of the storage battery system operation according to the second embodiment by the EMS when the equal mode is executed. Similarly, a flowchart showing the processing of the storage battery system operation according to the third embodiment by the EMS when the equal mode is executed. Similarly, a flowchart showing the processing of the storage battery system operation according to the fourth embodiment by EMS when the equalization mode is executed. The block diagram which showed the structure of the power supply system which concerns on 2nd Embodiment. Similarly, a flowchart showing the processing of the storage battery system operation according to the fifth embodiment by EMS when the equalization mode is executed. Similarly, a flowchart showing the processing of the storage battery system operation according to the sixth embodiment by EMS when the equalization mode is executed. Similarly, a flowchart showing the continuation of FIG.

Hereinafter, the power supply system 1 according to the first embodiment will be described with reference to FIG.

It is assumed that the power supply system 1 is applied to a residential block T (aggregate of houses H) composed of a plurality of detached houses (houses H). Specifically, in the residential block T, the first house H1, the second house H2, ..., The Nth house HN are provided as a plurality of (detached) houses H. In the residential block T, the electric power retailer purchases electric power from the electric power company (grid power supply S) in a lump sum, and the purchased electric power is appropriately supplied (sold) to each house H.

The electric power supply system 1 appropriately supplies (accommodates) electric power, etc. purchased in bulk from an electric power company by an electric power retailer among a plurality of houses H (first house H1, second house H2, ..., Nth house HN). ) Is a system for doing. The power supply system 1 mainly includes a sensor unit 10, a plurality of residential storage battery systems 20 (first residential storage battery system 21, second residential storage battery system 22, ..., Nth residential storage battery system 2N), and a shared storage battery system. 30, a plurality of residential photovoltaic power generation systems 40 (first residential photovoltaic power generation system 41, second residential photovoltaic power generation system 42, ..., Nth residential photovoltaic power generation system 4N), shared photovoltaic power generation It includes a system 50 and an EMS 60.

A plurality of houses H (first house H1, second house H2, ..., Nth house HN) are buildings in which people live. Appropriate electric appliances are provided in each house H, and electric power is consumed.

Further, each house H is connected to the grid power supply S. Specifically, each house H is connected to the system power supply S via a distribution line L whose upstream end is connected to the system power supply S and whose downstream end is branched and connected to each house H. Be connected.

The sensor unit 10 detects the electric power flowing through the distribution line L. The sensor unit 10 includes a shared sensor 10T, a first sensor 11, a second sensor 12, ..., And an Nth sensor 1N.

The shared sensor 10T, the first sensor 11, the second sensor 12, ..., And the Nth sensor 1N each detect the electric power flowing through the arrangement location. The shared sensor 10T, the first sensor 11, the second sensor 12, ..., The Nth sensor 1N are configured to be capable of outputting signals related to the detection results, respectively. The shared sensor 10T, the first sensor 11, the second sensor 12, ..., The Nth sensor 1N are each provided so as to correspond to a predetermined storage battery system, and are electrically connected to the corresponding residential storage battery system. ..

Specifically, the shared sensor 10T is electrically connected to the shared storage battery system 30 described later. Further, the first sensor 11 is electrically connected to the first residential storage battery system 21 described later. Further, the second sensor 12 is electrically connected to the second residential storage battery system 22 described later. Further, the Nth sensor 1N is electrically connected to the Nth residential storage battery system 2N, which will be described later.

Further, the shared sensor 10T, the first sensor 11, the second sensor 12, ..., The Nth sensor 1N are arranged on the distribution line L immediately upstream of the connection point to which the corresponding storage battery system is connected. .. Specifically, the shared sensor 10T, the first sensor 11, the second sensor 12, ..., The Nth sensor 1N are the shared connection point PT, the first connection point P1, and the second connection described later in the distribution line L, respectively. Point P2, ..., Arranged immediately upstream of the N-th connection point PN.

The plurality of residential storage battery systems 20 (first residential storage battery system 21, second residential storage battery system 22, ..., Nth residential storage battery system 2N) are a plurality of residential photovoltaic power generation systems 40 (from which will be described later). More specifically, it is a system for appropriately charging the power from the corresponding residential photovoltaic power generation system 40) among the plurality of residential photovoltaic power generation systems 40 and appropriately discharging the power. Each residential storage battery system 20 includes a storage battery that can be charged and discharged, a power conditioner that controls charging and discharging of the storage battery, and the like. Each residential storage battery system 20 is provided so as to correspond to a predetermined residential H (one residential storage battery system 20 is provided for one residential H). Each residential storage battery system 20 is owned by the predetermined house H (resident of the house H).

Further, each residential storage battery system 20 is connected to the middle part of the distribution line L. Specifically, the first residential storage battery system 21, the second residential storage battery system 22, ..., The Nth residential storage battery system 2N are the first connection point P1 and the second connection point P2 of the distribution wire L, respectively.・ ・, Connected to the Nth connection point PN. The first connection point P1, the second connection point P2, ..., The Nth connection point PN are in order from the downstream side (the plurality of residential sides) to the upstream side (system power supply S side) in the distribution line L. It is located in.

Further, each residential storage battery system 20 is used in a plurality of residential photovoltaic power generation systems 40 (more specifically, among the plurality of residential photovoltaic power generation systems 40, the corresponding residential photovoltaic power generation system 40) described later. It is configured so that the generated power is charged. Electric power from the grid power source S is obtained by charging each residential storage battery system 20 with the electric power generated by the residential photovoltaic power generation system 40 (particularly, surplus electric power) and discharging the charged electric power as necessary. It is possible to reduce the purchase amount of electricity and promote self-sufficiency of electricity in the residential area T.

Further, as described above, each residential storage battery system 20 is electrically connected to the sensors (first sensor 11, second sensor 12, ..., Nth sensor 1N) of the corresponding sensor unit 10. Each residential storage battery system 20 is configured so that a signal output from the sensor of the corresponding sensor unit 10 is input and the detection result of the sensor can be acquired based on the input signal. Each residential storage battery system 20 can perform load tracking operation for adjusting the amount of electric power to be discharged (output) based on the detection result of the sensor of the corresponding sensor unit 10.

Further, each residential storage battery system 20 has a plurality of modes as modes related to operation. The plurality of modes include an "eco mode", a "discharge mode" and a "stop mode". The "eco mode" is a mode in which the electric power from the residential photovoltaic power generation system 40 is preferentially used in the residential H, and the surplus electric power in the residential photovoltaic power generation system 40 is appropriately charged and discharged. Further, the discharge mode is a state in which each residential storage battery system 20 can be operably discharged (regardless of whether or not the remaining storage battery remains to the extent that it can be discharged) according to the power consumption of each house H. This is the mode. Further, the stop mode is a mode in which each residential storage battery system 20 is in a state in which it cannot be discharged in operation.

Further, each residential storage battery system 20 is configured to be able to detect the amount of electric power charged to itself (hereinafter, referred to as "remaining storage battery level").

The shared storage battery system 30 is a system for appropriately charging the electric power from the shared solar power generation system 50, which will be described later, and appropriately discharging the electric power. The shared storage battery system 30 includes a storage battery that can be charged and discharged, a power conditioner that controls charging and discharging of the storage battery, and the like. The shared storage battery system 30 is provided so as to be shared by a plurality of houses H (one shared storage battery system 30 is provided for the plurality of houses H). The shared storage battery system 30 is owned by an electric power retailer.

Further, the shared storage battery system 30 is connected to the middle part of the distribution line L. Specifically, the shared storage battery system 30 is connected to the shared connection point PT of the distribution line L. The shared connection point PT is arranged on the distribution line L on the upstream side (system power supply S side) of the Nth connection point PN.

Further, the shared storage battery system 30 is electrically connected to the sensor (shared sensor 10T) of the corresponding sensor unit 10. The shared storage battery system 30 is configured so that a signal output from the shared sensor 10T is input and the detection result of the shared sensor 10T can be acquired based on the input signal. The shared storage battery system 30 can perform load following operation for adjusting the amount of power to be discharged (output) based on the detection result of the shared sensor 10T.

A plurality of residential photovoltaic power generation systems 40 (first photovoltaic power generation system 41, second photovoltaic power generation system 42, ..., Nth photovoltaic power generation system 4N) use sunlight. It is a system for generating electricity. The residential photovoltaic power generation system 40 includes a solar cell module formed by combining solar cells (cells) into a plate shape, a power conditioner for adjusting electric power from the solar cell module, and the like. Each residential photovoltaic power generation system 40 is provided so as to correspond to a predetermined residential photovoltaic power generation system H (one residential photovoltaic power generation system 40 is provided for one residential photovoltaic power generation system H). Each residential photovoltaic power generation system 40 is owned by the predetermined house H (resident of the house H).

Further, each residential photovoltaic power generation system 40 is connected to the residential storage battery system 20 of the owned house H. Specifically, the first residential photovoltaic power generation system 41, the second residential photovoltaic power generation system 42, ..., The Nth residential photovoltaic power generation system 4N are the first residential storage battery system 21, the second, respectively. Residential storage battery system 22, ..., Connected to the Nth residential storage battery system 2N. In this way, each residential storage battery system 20 and each residential photovoltaic power generation system 40 are provided so as to correspond to each other.

Each residential photovoltaic power generation system 40 is configured to be able to supply electric power to the owned residential H (load). Each house H (resident of the house H) can appropriately use the electric power generated by the residential photovoltaic power generation system 40 owned by the house H. In addition, each residential photovoltaic power generation system 40 transfers the surplus electric power (surplus electric power) that was not used in the owned residential H to the residential storage battery system 20 of the residential H. Can be supplied to charge the residential storage battery system 20.

The shared photovoltaic power generation system 50 is a system for generating electricity using sunlight. The shared photovoltaic power generation system 50 includes a solar cell module formed by combining solar cells (cells) into a plate shape, a power conditioner for adjusting electric power from the solar cell module, and the like. The shared photovoltaic power generation system 50 is provided so as to be shared by a plurality of houses H (one shared photovoltaic power generation system 50 is provided for the plurality of houses H). The shared photovoltaic power generation system 50 is owned by an electric power retailer.

Further, the shared photovoltaic power generation system 50 is connected to the shared storage battery system 30. The shared photovoltaic power generation system 50 can supply the generated electric power to the shared storage battery system 30 and charge the shared storage battery system 30.

The EMS 60 is an energy management system (Energy Management System) that manages the operation of the power supply system 1. The EMS 60 includes a storage unit such as a RAM or ROM, an arithmetic processing unit such as a CPU, an input / output unit such as an I / O, and the like. The EMS 60 can perform predetermined arithmetic processing, storage processing, and the like. Various information, programs, and the like used when controlling the operation of the power supply system 1 are stored in advance in the EMS 60.

Further, the EMS 60 is electrically connected to the shared storage battery system 30 and each residential storage battery system 20. The EMS 60 can output a predetermined signal to the shared storage battery system 30 and each residential storage battery system 20 to control the operation of the shared storage battery system 30 and each residential storage battery system 20. Further, the EMS 60 is configured so that a predetermined signal can be input from the shared storage battery system 30 and each residential storage battery system 20.

In this way, the EMS 60 can acquire information regarding the operation of the shared storage battery system 30 and each residential storage battery system 20. Specifically, the EMS 60 can acquire the remaining battery level of each residential storage battery system 20. Further, the EMS 60 can acquire information on whether or not the shared storage battery system 30 and the residential storage battery system 20 are discharged (waiting for discharge).

Further, the EMS 60 is configured to be able to execute a plurality of modes as modes related to the operation of the power supply system 1. The plurality of modes include a "normal mode" and a "equal mode". The normal mode is a mode that allows a bias in the amount of discharge in a plurality of residential storage battery systems 20. The equalization mode is a mode for suppressing the unevenness of the discharge amount in the plurality of residential storage battery systems 20 (to equalize the discharge amount). It should be noted that which of the normal mode and the equal mode is executed is appropriately selected by, for example, an electric power retailer.

Next, the state of buying and selling electric power by the electric power retailer in the electric power supply system 1 configured as described above will be briefly described.

The electric power retailer appropriately sells the electric power purchased in bulk from the electric power company (grid power supply S) to each house H in response to a request from each house H. Residents of each house H can use the electric power purchased from the electric power company. Further, the electric power retailer purchases the electric power discharged from the storage battery system 20 for each house, and appropriately sells the electric power to each house H in response to a request from each house H. The price of electricity bought and sold by the electricity retailer is set appropriately.

In this way, electricity retailers can profit from buying and selling electricity. In addition, the residents of each house H can also make a profit by selling the electric power (that is, surplus electric power) of the residential storage battery system 20 to the electric power retailer.

The outline of the power supply (accommodation) mode when the normal mode is executed will be described below.

The electric power from the grid power source S is supplied to each house H via the distribution line L according to the power consumption of each house H. In this case, the first residential storage battery system 21 arranged on the most downstream side of the plurality of storage battery systems (shared storage battery system 30 and the plurality of residential storage battery systems 20) is loaded based on the detection result of the first sensor 11. Follow-up operation is performed to discharge a predetermined amount of electric power. In this way, the electric power discharged from the first residential storage battery system 21 is supplied to each residential H. When the electric power is discharged from the first residential storage battery system 21, the amount of electric power from the system power supply S decreases.

Further, when the power consumption of each house H cannot be covered only by the power from the first residential storage battery system 21, the insufficient power is supplied to each house H from the grid power source S. That is, the electric power from the system power supply S (the insufficient electric power) is supplied to each house H via the distribution line L. In this case, among the plurality of storage battery systems (shared storage battery system 30 and the plurality of residential storage battery systems 20), the second residential storage battery system 22 arranged one upstream side of the first residential storage battery system 21 is A load following operation is performed based on the detection result of the second sensor 12, and a predetermined amount of power is discharged. In this way, the electric power discharged from the second residential storage battery system 22 is supplied to each residential H. When the electric power is discharged from the second residential storage battery system 22, the amount of electric power from the system power source S is further reduced.

In this way, when the normal mode is executed, if the power consumption of each house H cannot be covered, the house arranged one upstream side from the residential storage battery system 20 (where discharge has started). The operation of starting the discharge from the storage battery system 20 is repeated. In this way, with respect to the power consumption of each house H, discharge is sequentially started from the storage battery system arranged on the downstream side to the storage battery system arranged on the upstream side among the plurality of storage battery systems.

If the power consumption of each house H cannot be covered even if the power is discharged from the Nth residential storage battery system 2N, the power from the shared storage battery system 30 is discharged. Then, if the power consumption of each house H cannot be covered even if the power is discharged from the shared storage battery system 30, the insufficient power is purchased from the grid power source S (the power purchased from the grid power supply S is used). , Supply to each house H).

In this way, in the power supply system 1, when the normal mode is executed, the electric power discharged from each residential storage battery system 20 is used not only by the resident (house H) who owns each residential storage battery system 20 but also by others. It will also be supplied to the residents (house H) of. That is, the surplus electric power of each residential photovoltaic power generation system 40 charged in each residential storage battery system 20 can be appropriately interchanged between the plurality of residential H.

As described above, the electric power discharged from each residential storage battery system 20 is the electric power generated in the house H (residential photovoltaic power generation system 40) that owns each residential storage battery system 20. Since the electric power discharged from each residential storage battery system 20 is once purchased by the electric power retailer, a fee corresponding to the electric power is paid to each residential H (resident).

Here, when the normal mode is executed, a problem may occur because the discharge amount in the plurality of residential storage battery systems 20 is biased.

Specifically, as described above, when the normal mode is executed, when the power consumption of each house H cannot be covered, the residential storage battery system 20 arranged on the downstream side is arranged on the upstream side. Since the discharge to the residential storage battery system 20 is sequentially started, the discharge amount of the residential storage battery system 20 arranged on the downstream side is larger than that on the upstream side. Therefore, the charge due to the interchange of electric power between the plurality of houses H (the charge paid by the electric power retailer to the residents of the house H) is the residential storage battery system 20 arranged on the downstream side rather than the upstream side. Many residents will get it.

For example, as shown in FIG. 2, when the power consumption of each house H can be covered only by the power discharged from the first residential storage battery system 21 arranged on the most downstream side, other residential storage battery systems. Power is not discharged from 20 (second residential storage battery system 22, Nth residential storage battery system 2N, etc.). In such a case, only the resident of the first house H1 who owns the storage battery system 21 for the first house can get the charge due to the power interchanged between the plurality of houses H.

In this way, when the normal mode is executed, the amount of discharge in the plurality of residential storage battery systems 20 is biased, so that the charges that can be obtained among the plurality of houses H (residents) become uneven, which is a problem. there were. In addition, since the amount of discharge in the plurality of residential storage battery systems 20 is uneven, the life (useful life) of the plurality of residential storage battery systems 20 becomes uneven, which is a problem. Further, if there is a residential storage battery system 20 that is not discharged while being fully charged due to a bias in the amount of discharge in the plurality of residential storage battery systems 20, the residential storage battery system 20 cannot charge the surplus electric power. , There was a problem in that the generated power could be wasted.

Therefore, in the power supply system 1, in order to solve the above-mentioned problems, the equal mode can be executed. In the equal mode, the operation (load tracking operation) of each residential storage battery system 20 in the normal mode is used as a base, and correction is made to suppress the bias of the discharge amount in the plurality of residential storage battery systems 20 (in each residential storage battery system 20). Processing such as setting a predetermined discharge priority for discharge) is performed.

The processing of the EMS 60 when the equalization mode is executed will be described below.

When the equalization mode is executed, the EMS 60 performs time zone processing. The time zone processing is a process of switching the mode of the residential storage battery system 20 to the "eco mode" according to the time zone.

During the time period when the residential photovoltaic power generation system 40 is irradiated with sunlight, the electric power generated by the residential photovoltaic power generation system 40 (particularly, surplus electric power) is charged to the residential storage battery system 20 for effective utilization. It is desirable to try. Therefore, the EMS 60 performs a process (time zone processing) of switching the mode of the residential storage battery system 20 to the "eco mode" during the time zone when the residential photovoltaic power generation system 40 is considered to be irradiated with sunlight.

In the following, the time zone processing by the EMS 60 will be specifically described with reference to FIG.

In step S101, the EMS 60 determines whether or not the current time (time) is the set time A.
Here, the set time A is a time (time zone) in which the residential photovoltaic power generation system 40 is considered to be irradiated with sunlight. That is, the set time A is a time when it is considered that power can be generated by the residential photovoltaic power generation system 40. The set time A is stored (set) in advance in the EMS 60. As the set time A, the daytime time is mainly set. For example, the set time A is set to "7:00 to 17:00" or the like.
When the EMS 60 determines that the current time is the set time A (Yes in step S101), the EMS 60 executes the process of step S102.

In step S102, the EMS 60 changes each residential storage battery system 20 to eco mode. Each residential storage battery system 20 set in the eco mode charges the surplus electric power from the residential photovoltaic power generation system 40 of each residential H.

In the state where each residential storage battery system 20 is set to the eco mode (that is, the set time A), each house H uses the electric power generated by the residential photovoltaic power generation system 40 owned by each house H. If the electric power alone is insufficient, the electric power charged in each residential storage battery system 20 or the electric power from the system power supply S is used. As described above, in the eco mode, the electric power generated by each residential photovoltaic power generation system 40 is preferentially used.

Further, in step S101, if the EMS 60 determines that the current time is not the set time A (No in step S101), the EMS 60 executes the process of step S103.

In step S103, the EMS 60 determines whether or not the current time (time) is the set time B.
Here, the set time B is a time (time zone) in which it is considered that the residential photovoltaic power generation system 40 is not irradiated with sunlight. That is, the set time B is a time when it is considered that power generation is impossible by the residential photovoltaic power generation system 40. The set time B is stored (set) in advance in the EMS 60. As the set time B, the time at night is mainly set. For example, the set time A is set to "17:00 to 7:00" or the like.
When the EMS 60 determines that the current time is the set time B (Yes in step S103), the EMS 60 executes the process of step S104.

In step S104, the EMS 60 executes a preset process. The specific contents of the preset processing will be described later.
The EMS 60 executes the process of step S104 and then executes the process of step S105.

In step S105, the EMS 60 executes the mode switching process. The specific contents of the mode switching process will be described later.

In this way, after executing the process of step S102 or step S105, and when it is determined in step S103 that the current time is not the set time B, the EMS 60 ends the time zone process.

Next, the preset processing (step S104) by the EMS 60 will be described.

In the preset processing, the EMS 60 sets the discharge priority and the mode related to the operation of each residential storage battery system 20. Further, in the processing of the storage battery system operation, the EMS 60 specifically operates each residential storage battery system 20 based on the settings made in the preset processing. The discharge priority is a criterion for determining which of the residential storage battery systems 20 is preferentially discharged.

In the following, the preset processing by the EMS 60 will be specifically described with reference to FIG.

In step S111, the EMS 60 acquires the remaining battery level of each residential storage battery system 20. The EMS 60 executes the process of step S111 and then executes the process of step S112.

In step S112, the EMS 60 sets the discharge priority of each residential storage battery system 20 based on the remaining battery level acquired in step S111. Specifically, the EMS 60 sets the highest discharge priority (first, second, ..., Nth) in descending order of the remaining battery level for each residential storage battery system 20.

Here, FIG. 5 shows an example of the set discharge priority. Note that FIG. 5 shows, as an example, a case where the residential storage battery system 20 arranged on the upstream side of the plurality of residential storage battery systems 20 has a larger remaining battery capacity than the downstream side. .. In such a case, the EMS 60 sets the discharge priority of the Nth residential storage battery system 2N, which is the first in the order of the highest remaining battery capacity, to the first. Then, the EMS 60 sequentially sets the discharge priority, and sets the discharge priority of the second residential storage battery system 22 in which the order of the number of remaining storage batteries is N-1th. Is set to, and the discharge priority of the first residential storage battery system 21 in which the order of the number of remaining storage batteries is Nth is set to Nth.

The EMS 60 executes the process of step S112 and then executes the process of step S113.

In step S113, the EMS 60 sets the highest (first) residential storage battery system 20 to the discharge mode based on the discharge priority set in step S112, and sets the other (second, ..., N). Set the residential storage battery system 20 (-1st, Nth) to the stop mode.

That is, in the example shown in FIG. 5, among the plurality of residential storage battery systems 20, the highest (first) Nth residential storage battery system 2N is set to the discharge mode, and the other residential storage battery systems 20 are set. (Second residential storage battery system 22, first residential storage battery system 21, etc.) is set to the stop mode.

In this way, the EMS 60 ends the preset process after executing the process of step S113.

Next, the processing of the storage battery system operation according to the first embodiment by the EMS 60 will be described.

In the processing of the storage battery system operation, the EMS 60 specifically operates each residential storage battery system 20 based on the settings made in the preset processing.

Hereinafter, the processing of the storage battery system operation according to the first embodiment by the EMS 60 will be specifically described with reference to FIG.

In step S121, the EMS 60 determines whether or not the shared storage battery system 30 is discharged. When the EMS 60 determines that the shared storage battery system 30 is discharged (Yes in step S121), the EMS 60 executes the process of step S122. When the shared storage battery system 30 is discharged, each house H is discharged even if power is discharged from all the residential storage battery systems 20 set in the discharge mode (that is, in a state in which the shared storage battery system 30 can be discharged in operation). It shows the case where the power consumption of is not covered.

In step S122, the EMS 60 determines whether or not the residential storage battery system 20 having the lowest discharge priority is set to the discharge mode. When the EMS 60 determines that the residential storage battery system 20 having the lowest discharge priority is not set to the discharge mode (No in step S122), the EMS 60 executes the process of step S123. The case where the residential storage battery system 20 having the lowest discharge priority is not set to the discharge mode indicates the case where the residential storage battery system 20 set to the stop mode exists.

In step S123, the EMS 60 changes the residential storage battery system 20 having the highest discharge priority among the residential storage battery systems 20 currently set to the stop mode to the discharge mode. In this way, the EMS 60 increases the number of residential storage battery systems 20 set in the discharge mode, and thus increases the amount of power from all the residential storage battery systems 20 set in the discharge mode. The EMS 60 executes the process of step S123 and then executes the process of step S124.

In this way, even if the electric power is discharged from all the residential storage battery systems 20 set in the discharge mode, the power consumption of each house H cannot be covered (Yes in step S121), and the stop mode is set. When the residential storage battery system 20 is present (No in step S122), all the houses set in the discharge mode are set by increasing the number of the residential storage battery systems 20 set in the discharge mode. The amount of power from the storage battery system 20 can be increased (step S123).

In step S124, the EMS 60 determines whether or not the shared storage battery system 30 is on standby for discharge. When the EMS 60 determines that the shared storage battery system 30 is not in discharge standby (No in step S124), the EMS 60 executes the process of step S122 again. The case where the shared storage battery system 30 is not in discharge standby means that the power consumption of each house H cannot be covered even if the power is discharged from all the residential storage battery systems 20 set in the discharge mode (shared storage battery system). 30 is also when the electric power is discharged).

In such a case, the EMS 60 again executes the process of step S122, and if possible (if there is a residential storage battery system 20 set in the stop mode), all set to the discharge mode. The number of residential storage battery systems 20 set in the discharge mode is increased so as to increase the amount of electric energy from the residential storage battery system 20 of the above.

Further, in step S124, when the EMS 60 determines that the shared storage battery system 30 is in discharge standby (Yes in step S124), the EMS 60 ends the processing of the storage battery system operation. The case where the shared storage battery system 30 is in discharge standby means that the power consumption of each house H is covered by the power discharged from each residential storage battery system 20 set in the discharge mode (shared storage battery system 30). When it is not necessary to discharge).

Further, in step S122, when the EMS 60 determines that the residential storage battery system 20 having the lowest discharge priority is set to the discharge mode (Yes in step S122), the EMS 60 ends the processing of the storage battery system operation. The case where the residential storage battery system 20 having the lowest discharge priority is set to the discharge mode indicates the case where the residential storage battery system 20 set to the stop mode does not exist.

In such a case, since the EMS 60 cannot increase the number of the residential storage battery systems 20 set in the discharge mode, the electric energy from all the residential storage battery systems 20 set in the discharge mode should be increased. I can't do that. In this way, when the residential storage battery system 20 having the lowest discharge priority is set to the discharge mode, the insufficient power is purchased from the system power supply S, and the purchased power is transferred to each house H. Will be supplied.

Further, in step S121, when the EMS 60 determines that the shared storage battery system 30 is not discharged (No in step S121), the EMS 60 ends the processing of the storage battery system operation. The case where the shared storage battery system 30 is not discharged means that the power consumption of each house H is covered by the power discharged from each residential storage battery system 20 set in the discharge mode (shared storage battery system 30). When it is not necessary to discharge).

In this way, by controlling the operation (discharge) of the residential storage battery system 20 by the processing of the storage battery system operation according to the first embodiment, the amount of discharge in the plurality of residential storage battery systems 20 is biased (remaining amount of the storage battery). It is possible to eliminate the bias) (it is possible to effectively prevent the discharge from being biased to the specific residential storage battery system 20). In this way, by eliminating the bias caused in the amount of discharge in the plurality of residential storage battery systems 20, it is possible to equalize the charges that can be obtained among the plurality of houses H (residents). Hereinafter, a specific description will be made with reference to FIG. 7.

Here, FIG. 7 shows an electric power supply mode when the equal mode (processing of the storage battery system operation) is executed in the example of the discharge priority shown in FIG. In the example shown in FIG. 5, since the storage battery system set to the discharge mode is only the Nth residential storage battery system 2N, the power consumption of each house H is discharged from the Nth residential storage battery system 2N. Power is being supplied.

Then, if the power consumption of each house H cannot be covered by the power discharged from the Nth residential storage battery system 2N (Yes in step S121), the residential storage battery system currently set to the stop mode. Of the 20 units, the residential storage battery system 20 having the highest discharge priority (in the present embodiment, the N-1 residential storage battery system shown in FIG. 5) is changed to the discharge mode (step S123). In this way, the number of the residential storage battery systems 20 set in the discharge mode is increased from one to two, and all the residential storage battery systems 20 set in the discharge mode (the Nth residential storage battery system 2N and the above). Increase the amount of power from the N-1 residential storage battery system).

In this way, by setting a predetermined discharge priority for the discharge of each residential storage battery system 20 by the processing of the storage battery system operation, the bias of the discharge amount (the bias of the remaining amount of the storage battery) in the plurality of residential storage battery systems 20 is eliminated. Can be planned. In this way, by eliminating the bias caused in the amount of discharge in the plurality of residential storage battery systems 20, it is possible to equalize the charges that can be obtained among the plurality of houses H (residents).

Further, by eliminating the bias caused in the discharge amount in the plurality of residential storage battery systems 20, it is possible to eliminate the bias in the number of charge / discharge cycles in the plurality of residential storage battery systems 20. In this way, the number of charge / discharge cycles in the plurality of residential storage battery systems 20 can be equalized, and thus the life (useful life) of the plurality of residential storage battery systems 20 can be equalized.

Further, by preferentially discharging the residential storage battery system 20 having a large remaining amount of the storage battery, it becomes easy to secure free capacity in the residential storage battery system 20. As a result, it becomes easy to avoid a situation in which the electric power generated by the residential photovoltaic power generation system 40 cannot charge the residential storage battery system 20 (there is no free capacity). Therefore, it is possible to prevent the electric power generated by the residential photovoltaic power generation system 40 from being wasted.

Next, the processing of the storage battery system operation according to the second embodiment (another example of the first embodiment) by the EMS 60 will be described with reference to FIG.

The process of operating the storage battery system according to the second embodiment differs from the process of operating the storage battery system according to the first embodiment in that the process of step S124 is not performed. Specifically, the EMS 60 temporarily ends the processing of the storage battery system operation after executing the processing of step S123, and after a certain period of time elapses, starts the processing of the storage battery system operation again from step S121.

In this way, if the EMS 60 determines that the shared storage battery system 30 is discharged after the process of step S123 is executed (Yes in step S121), the residential storage battery system 20 set to the stop mode exists. If (No in step S122), the electric energy from all the residential storage battery systems 20 set in the discharge mode is increased by increasing the number of the residential storage battery systems 20 set in the discharge mode. Can be done (step S123).

Further, if it is determined that the shared storage battery system 30 is not discharged (No in step S121) after the process of step S123 is executed, the EMS 60 is discharged from each residential storage battery system 20 set to the discharge mode. Since the power consumption of each house H is covered by the generated power (because the shared storage battery system 30 does not need to be discharged), the processing of the storage battery system operation is temporarily terminated.

In this way, the processing of the storage battery system operation according to the second embodiment controls the operation (discharge) of the residential storage battery system 20 in the same manner as the processing of the storage battery system operation according to the first embodiment. It is possible to eliminate the bias of the discharge amount (the bias of the remaining amount of the storage battery) in the residential storage battery system 20. In this way, by eliminating the bias caused in the amount of discharge in the plurality of residential storage battery systems 20, it is possible to equalize the charges that can be obtained among the plurality of houses H (residents).

Next, with reference to FIG. 9, the processing of the storage battery system operation according to the third embodiment by the EMS 60 when the equal mode is executed will be described.

The processing of the storage battery system operation according to the third embodiment differs from the processing of the storage battery system operation according to the first embodiment in that the processing of steps S131 to S134 is added. Hereinafter, for convenience, the processing of the storage battery system operation according to the third embodiment will be described as different from the processing of the storage battery system operation according to the first embodiment (processes from steps S131 to S134), and the first embodiment will be described. The same points as the processing of the storage battery system operation (processing of steps S121 to S124) will be omitted.

In step S131, the EMS 60 determines whether or not the power purchased from the system power source S in the shared storage battery system 30 is larger than the predetermined minimum discharge threshold value a. When the EMS 60 determines that the power purchased from the system power source S in the shared storage battery system 30 is larger than the minimum discharge threshold value a (Yes in step S131), the EMS 60 executes the process of step S132.

Here, the minimum discharge threshold value a is a value of electric power set by a regulation with an electric power company to be purchased from the grid power supply S when at least one or more residential storage battery systems 20 are discharging. Yes, for example 200W. That is, in the present embodiment, the case where the power purchased from the system power source S in the shared storage battery system 30 is larger than the minimum discharge threshold a is the case where at least one or more residential storage battery systems 20 are discharging. However, if the power consumption of each house H cannot be covered even if the power is discharged from all the residential storage battery systems 20 set in the discharge mode (the insufficient power is purchased from the system power supply S). If) is shown.

In step S132, the EMS 60 determines whether or not the residential storage battery system 20 having the lowest discharge priority is set to the discharge mode. The content of this process is the same as in step S122. When the EMS 60 determines that the residential storage battery system 20 having the lowest discharge priority is not set to the discharge mode (No in step S132), the EMS 60 executes the process of step S133.

In step S133, the EMS 60 changes the residential storage battery system 20 having the highest discharge priority among the residential storage battery systems 20 currently set to the stop mode to the discharge mode. The content of this process is the same as in step S123. The EMS 60 executes the process of step S134 after executing the process of step S133.

In this way, even if the electric power is discharged from all the residential storage battery systems 20 set in the discharge mode, the power consumption of each house H cannot be covered (Yes in step S131), and the stop mode is set. When the residential storage battery system 20 is present (No in step S132), all the houses set in the discharge mode are set by increasing the number of the residential storage battery systems 20 set in the discharge mode. The amount of power from the storage battery system 20 can be increased (step S133).

In step S134, the EMS 60 determines whether or not the power purchased from the system power source S in the shared storage battery system 30 is equal to or less than the minimum discharge threshold value a. When the EMS 60 determines that the power purchased from the system power source S in the shared storage battery system 30 is not equal to or less than the minimum discharge threshold value a (No in step S134), the EMS 60 executes the process of step S132 again. When the power purchased from the grid power supply S in the shared storage battery system 30 is not equal to or less than the minimum discharge threshold a, even if the power is discharged from all the residential storage battery systems 20 set in the discharge mode, each house The case where the power consumption of H cannot be covered (the case where the shared storage battery system 30 also discharges the power) is shown.

In such a case, the EMS 60 again executes the process of step S132, and if possible (if there is a residential storage battery system 20 set in the stop mode), all set to the discharge mode. The number of residential storage battery systems 20 set in the discharge mode is increased so as to increase the amount of electric energy from the residential storage battery system 20 of the above.

Further, in step S134, when the EMS 60 determines that the power purchased from the system power source S in the shared storage battery system 30 is equal to or less than the minimum discharge threshold value a (Yes in step S134), the EMS 60 ends the processing of the storage battery system operation. The case where the electric power purchased from the system power source S in the shared storage battery system 30 is equal to or less than the minimum discharge threshold a is the case where at least one or more residential storage battery systems 20 are discharging. , When the power consumed by each house H is covered by the power discharged from each residential storage battery system 20 set in the discharge mode (when the insufficient power is not purchased from the grid power source S), or Alternatively, it shows the case where all the residential storage battery systems 20 are not discharging.

Further, in step S132, when the EMS 60 determines that the residential storage battery system 20 having the lowest discharge priority is set to the discharge mode (Yes in step S132), the storage battery is the same as in the case of Yes in step S122. Ends system operation processing.

As described above, among the processing of the storage battery system operation according to the third embodiment, the processing from step S131 to step S134 is the processing of the storage battery system operation according to the first embodiment (processing from step S121 to step S124). Similarly, by controlling the operation (discharge) of the residential storage battery system 20, it is possible to eliminate the bias in the amount of discharge (bias in the remaining amount of the storage battery) in the plurality of residential storage battery systems 20. In this way, by eliminating the bias caused in the amount of discharge in the plurality of residential storage battery systems 20, it is possible to equalize the charges that can be obtained among the plurality of houses H (residents).

Further, in step S131, if the EMS 60 determines that the power purchased from the system power source S in the shared storage battery system 30 is not larger than the minimum discharge threshold value a (No in step S131), the process of step S121 is executed. The case where the electric power purchased from the system power source S in the shared storage battery system 30 is not larger than the minimum discharge threshold a is the case where at least one or more residential storage battery systems 20 are discharging. In addition, whether the power consumption of each house H is covered by the power discharged from each residential storage battery system 20 set in the discharge mode (when the insufficient power is not purchased from the grid power source S). Or, the case where all the residential storage battery systems 20 are not discharging is shown.

Thus, in steps S121 to S124, the EMS 60 executes the same process as the process of operating the storage battery system according to the first embodiment. That is, among the processing of the storage battery system operation according to the third embodiment, the processing from step S121 to step S124 causes the operation (discharge) of the residential storage battery system 20 to be the same as the processing of the storage battery system operation according to the first embodiment. ), It is possible to eliminate the bias of the discharge amount (the bias of the remaining amount of the storage battery) in the plurality of residential storage battery systems 20. In this way, by eliminating the bias caused in the amount of discharge in the plurality of residential storage battery systems 20, it is possible to equalize the charges that can be obtained among the plurality of houses H (residents).

As described above, in the processing of the storage battery system operation according to the third embodiment, it is determined whether or not the power purchased from the system power source S in the shared storage battery system 30 is larger than the minimum discharge threshold a (step S131). Based on two different determinations, that is, whether or not the shared storage battery system 30 is discharged (step S121), the bias caused in the discharge amount in the plurality of residential storage battery systems 20 is eliminated. That is, even if one of the two judgments is not made accurately for some reason, the amount of discharge in the plurality of residential storage battery systems 20 is biased based on the remaining one judgment. Since this can be eliminated, it is possible to more reliably equalize the charges that can be obtained among the plurality of houses H (residents).

Although the process of step S134 is executed in the process of operating the storage battery system according to the third embodiment, the process is omitted as in step S124 of the process of operating the storage battery system according to the first embodiment. It is also possible (see the processing of the storage battery system operation according to the second embodiment (another example of the first embodiment)).

Next, with reference to FIG. 10, the processing of the storage battery system operation according to the fourth embodiment by the EMS 60 when the equal mode is executed will be described.

The process of operating the storage battery system according to the fourth embodiment differs from the process of operating the storage battery system according to the first embodiment in that the processes of steps S141 to S143 are added. Hereinafter, for convenience, the processing of the storage battery system operation according to the fourth embodiment will be described as different from the processing of the storage battery system operation according to the first embodiment (processes from steps S141 to S143), and the first embodiment will be described. The same points as the processing of the storage battery system operation (processing of steps S121 to S124) will be omitted.

If No in step S121, Yes in step S122, or Yes in step S124, the EMS 60 executes the process of step S141.

The case where No is set in step S121 and the case where Yes is set in step S124 indicate a case where the power consumption of each house H is covered (a case where the shared storage battery system 30 does not need to be discharged). .. Further, the case of Yes in step S122 indicates the case where the residential storage battery system 20 set in the stop mode does not exist. As described above, when No in step S121, Yes in step S122, or Yes in step S124, the process of increasing the number of residential storage battery systems 20 set in the discharge mode is performed. Indicates a case where it is not performed (cannot be performed or does not need to be performed).

As described above, in the process of operating the storage battery system according to the fourth embodiment, the EMS 60 executes the process of step S141 when the process of increasing the number of the residential storage battery systems 20 set in the discharge mode is not performed.

In step S141, the EMS 60 determines whether or not each residential storage battery system 20 set in the discharge mode has a residential storage battery system 20 that is on standby for discharge. When the EMS 60 determines that each residential storage battery system 20 set in the discharge mode has a residential storage battery system 20 that is on standby for discharge (Yes in step S141), the EMS 60 executes the process of step S142. When each residential storage battery system 20 set in the discharge mode has a residential storage battery system 20 that is on standby for discharge, the power consumption of each residential H is covered, and the number of residential storage batteries is larger than necessary. The case where the system 20 is set to the discharge mode is shown.

In step S142, the EMS 60 changes the residential storage battery system 20 having the lowest discharge priority among all the residential storage battery systems 20 set in the discharge mode to the stop mode. In this way, the EMS 60 reduces the number of the residential storage battery systems 20 set in the discharge mode, and minimizes the discharge from the residential storage battery systems 20 having a low discharge priority. The EMS 60 executes the process of step S142 and then executes the process of step S143.

In step S143, the EMS 60 determines whether or not all the residential storage battery systems 20 set in the discharge mode are discharged. When the EMS 60 determines that all the residential storage battery systems 20 set in the discharge mode are not discharged (No in step S143), the process of step S142 is executed again.

When all the residential storage battery systems 20 set in the discharge mode are not discharged (No in step S143), the discharge standby is performed among all the residential storage battery systems 20 set in the discharge mode. The case where there is a residential storage battery system 20, that is, the case where the power consumption of each house H is covered and the number of residential storage battery systems 20 more than necessary is set to the discharge mode is shown.

In such a case, the EMS 60 re-executes the process of step S142 to minimize discharge from the residential storage battery system 20 having the lowest discharge priority, so that the residential storage battery system 20 having the lowest discharge priority 20 does not discharge as much as possible. To stop mode.

Further, in step S143, when the EMS 60 determines that all the residential storage battery systems 20 set in the discharge mode are discharged (Yes in step S143), the EMS 60 ends the processing of the storage battery system operation. The case where all the residential storage battery systems 20 set in the discharge mode are discharged indicates the case where the number of the residential storage battery systems 20 set in the discharge mode cannot be further reduced. ..

Further, in step S141, when the EMS 60 determines that each residential storage battery system 20 set in the discharge mode does not have the residential storage battery system 20 on standby for discharge (No in step S141), the EMS 60 processes the operation of the storage battery system. finish. When each residential storage battery system 20 set in the discharge mode does not have the residential storage battery system 20 in the discharge standby mode, the number of the residential storage battery systems 20 set in the discharge mode should be further reduced. Indicates a case where

In this way, by controlling the operation (discharge and discharge stop) of the residential storage battery system 20 by the processing of the storage battery system operation according to the fourth embodiment, for example, rather than the processing of the storage battery system operation according to the first embodiment. While finely adjusting the discharge amount from the residential storage battery system 20, it is possible to eliminate the bias in the discharge amount (bias in the remaining amount of the storage battery) in the plurality of residential storage battery systems 20. In this way, by eliminating the bias caused in the amount of discharge in the plurality of residential storage battery systems 20, it is possible to more reliably equalize the charges that can be obtained among the plurality of houses H (residents).

In the process of operating the storage battery system according to the fourth embodiment, the process of step S143 is executed, but the process is omitted as in step S124 of the process of operating the storage battery system according to the first embodiment. It is also possible (see the processing of the storage battery system operation according to the second embodiment (another example of the first embodiment)).

Hereinafter, the power supply system 200 according to the second embodiment will be described with reference to FIG.

As shown in FIG. 11, the power supply system 200 according to the second embodiment differs from the power supply system 1 according to the first embodiment in the shared storage battery system 30, the shared photovoltaic power generation system 50, and the sensor unit 10. The point is that the shared sensor 10T is not provided.

In such a power supply system 200, as in the power supply system 1, the equal mode can be executed in order to solve the problem as described above. Further, when the equal mode is executed, the EMS 60 performs time zone processing, in which preset processing and storage battery system operation processing are performed. In the power supply system 200, the preset processing by the EMS 60 when the equal mode is executed is the same as that in the power supply system 1, so the description thereof will be omitted.

In the following, with reference to FIG. 12, in the power supply system 200 according to the second embodiment, processing of the storage battery system operation according to the first embodiment by the EMS 60 when the equal mode is executed (hereinafter, “fifth embodiment” for convenience. It is referred to as "processing of storage battery system operation according to the form").

In step S161, in step S161, the electric power purchased from the system power source S in the residential storage battery system (Nth residential storage battery system 2N in the present embodiment) arranged on the most upstream side is the minimum discharge threshold value a. Determine if it is greater than. When the EMS 60 determines that the power purchased from the system power source S in the Nth residential storage battery system 2N is larger than the minimum discharge threshold value a (Yes in step S161), the EMS 60 executes the process of step S162.

The case where the electric power purchased from the system power source S in the Nth residential storage battery system 2N is larger than the minimum discharge threshold a is the case where at least one or more residential storage battery systems 20 are discharging. In addition, when the power consumption of each house H cannot be covered even if the power is discharged from all the residential storage battery systems 20 set in the discharge mode (when the insufficient power is purchased from the grid power supply S). ) Is shown.

In step S162, the EMS 60 determines whether or not the residential storage battery system 20 having the lowest discharge priority is set to the discharge mode. The content of this process is the same as in step S122. When the EMS 60 determines that the residential storage battery system 20 having the lowest discharge priority is not set to the discharge mode (No in step S162), the EMS 60 executes the process of step S163.

In step S163, the EMS 60 changes the residential storage battery system 20 having the highest discharge priority among the residential storage battery systems 20 currently set to the stop mode to the discharge mode. The content of this process is the same as in step S123. The EMS 60 executes the process of step S163 and then executes the process of step S164.

In step S164, in step S164, the electric power purchased from the system power source S in the residential storage battery system (Nth residential storage battery system 2N in the present embodiment) arranged on the most upstream side is the minimum discharge threshold value a. Judge whether or not it is as follows. When the EMS 60 determines that the power purchased from the system power source S in the Nth residential storage battery system 2N is not equal to or less than the minimum discharge threshold value a (No in step S164), the EMS 60 executes the process of step S162 again.

The case where the electric power purchased from the system power source S in the Nth residential storage battery system 2N is not equal to or less than the minimum discharge threshold a is the case where at least one or more residential storage battery systems 20 are discharging. In addition, when the power consumption of each house H cannot be covered even if the power is discharged from all the residential storage battery systems 20 set in the discharge mode (when the insufficient power is purchased from the grid power supply S). ) Is shown.

In such a case, the EMS 60 again executes the process of step S162, and if possible (if there is a residential storage battery system 20 set in the stop mode), all set to the discharge mode. The number of residential storage battery systems 20 set in the discharge mode is increased so as to increase the amount of electric energy from the residential storage battery system 20 of the above.

Further, in step S164, when the EMS 60 determines that the power purchased from the system power source S in the Nth residential storage battery system 2N is equal to or less than the minimum discharge threshold value a (Yes in step S164), the processing of the storage battery system operation is performed. To finish. The power purchased from the grid power source S in the Nth residential storage battery system 2N is equal to or less than the minimum discharge threshold a, or the case where at least one or more residential storage battery systems 20 are discharging. If the power consumed by each house H is covered by the power discharged from each residential storage battery system 20 set in the discharge mode (the insufficient power is not purchased from the grid power source S). Case), or all the residential storage battery systems 20 are not discharging.

Further, in step S162, when the EMS 60 determines that the residential storage battery system 20 having the lowest discharge priority is set to the discharge mode (Yes in step S162), the storage battery is the same as in the case of Yes in step S122. Ends system operation processing.

In such a case, since the EMS 60 cannot increase the number of the residential storage battery systems 20 set in the discharge mode, the electric energy from all the residential storage battery systems 20 set in the discharge mode should be increased. I can't do that. In this way, when the residential storage battery system 20 having the lowest discharge priority is set to the discharge mode, the insufficient power is purchased from the system power supply S, and the purchased power is transferred to each house H. Will be supplied.

As described above, by controlling the operation (discharge) of the residential storage battery system 20 in the same manner as the processing of the storage battery system operation according to the first embodiment by the processing of the storage battery system operation according to the fifth embodiment, a plurality of storage battery systems are operated. It is possible to eliminate the bias of the discharge amount (the bias of the remaining amount of the storage battery) in the residential storage battery system 20. In this way, by eliminating the bias caused in the amount of discharge in the plurality of residential storage battery systems 20, it is possible to equalize the charges that can be obtained among the plurality of houses H (residents).

Further, in the processing of the storage battery system operation according to the fifth embodiment, unlike the processing of the storage battery system operation according to the first embodiment, it is based on the determination of whether or not the shared storage battery system 30 is discharged (step S121). However, based on the determination (step S161) of whether or not the power purchased from the system power source S in the Nth residential storage battery system 2N is larger than the minimum discharge threshold a, the plurality of residential storage battery systems 20 We are trying to eliminate the bias caused in the amount of discharge. In this way, even if the shared storage battery system 30 is not provided, it is possible to equalize the charges that can be obtained among the plurality of houses H (residents).

Although the process of step S164 is executed in the process of operating the storage battery system according to the fifth embodiment, the process is omitted as in step S124 of the process of operating the storage battery system according to the first embodiment. It is also possible (see the processing of the storage battery system operation according to the second embodiment (another example of the first embodiment)).

In the following, with reference to FIGS. 13 and 14, in the power supply system 200 according to the second embodiment, processing of the storage battery system operation according to the second embodiment by the EMS 60 when the equal mode is executed (hereinafter, for convenience, " The process of operating the storage battery system according to the sixth embodiment ”) will be described.

The processing of the storage battery system operation according to the sixth embodiment differs from the processing of the storage battery system operation according to the fifth embodiment in that the processing of steps S171 to S181 is added. Hereinafter, for convenience, the processing of the storage battery system operation according to the sixth embodiment will be described as different from the processing of the storage battery system operation according to the fifth embodiment (processes from steps S171 to S181), and the fifth embodiment will be described. The same points as the processing of the storage battery system operation (processing of steps S161 to S164) will be omitted.

If Yes in step S161, the EMS 60 executes the process of step S171.

In step S171, the EMS 60 determines whether or not the remaining battery level of each residential storage battery system 20 is larger than the predetermined dischargeable threshold value b. When the EMS 60 determines that the remaining battery level of each residential storage battery system 20 is larger than the dischargeable threshold value b (Yes in step S171), the EMS 60 executes the process of step S162. Further, the EMS 60 determines that the remaining battery level of each residential storage battery system 20 is not larger than the dischargeable threshold value b (the remaining battery level of at least one or more residential storage battery systems 20 is the dischargeable threshold value b or less). Then (No in step S171), the process of step S172 is executed.

Here, the dischargeable threshold value b is the lower limit value of the remaining amount of the storage battery for the residential storage battery system 20 to discharge. That is, in the present embodiment, the case where the remaining amount of the storage battery of each residential storage battery system 20 is larger than the dischargeable threshold b indicates the case where all the residential storage battery systems 20 can be discharged if they are in the discharge mode. There is. Further, when the remaining battery level of each residential storage battery system 20 is not larger than the dischargeable threshold value b (the remaining battery level of at least one or more residential storage battery systems 20 is equal to or less than the dischargeable threshold value b), at least It shows the case where one or more residential storage battery systems 20 cannot be discharged even in the discharge mode.

In step S172, the EMS 60 determines whether or not the remaining battery level of each residential storage battery system 20 is equal to or less than the dischargeable threshold value b. When the EMS 60 determines that the remaining battery level of each residential storage battery system 20 is not equal to or less than the dischargeable threshold value b (No in step S172), the process of step S173 is executed. The case where the remaining battery level of each residential storage battery system 20 is not equal to or less than the dischargeable threshold value b indicates the case where at least one or more residential storage battery systems 20 can be discharged if they are in the discharge mode.

In step S173, the EMS 60 extracts only the residential storage battery system 20 in which the remaining amount of the storage battery is larger than the dischargeable threshold value b, and sets the discharge priority of each of the extracted residential storage battery systems 20. Specifically, the EMS 60 acquires the remaining amount of the storage battery of each of the extracted residential storage battery systems 20, and sets the discharge priority of each of the extracted residential storage battery systems 20 based on the acquired remaining amount of the storage battery. To do. The EMS 60 executes the process of step S173 and then executes the process of step S174.

In step S174, the EMS 60 determines whether or not the residential storage battery system 20 having the lowest discharge priority set in step S173 is set to the discharge mode. When the EMS 60 determines that the residential storage battery system 20 having the lowest discharge priority is not set to the discharge mode (No in step S174), the EMS 60 executes the process of step S175.

In step S175, the EMS 60 is the residential storage battery system 20 whose discharge priority is set in step S173, and is the house having the highest discharge priority among the residential storage battery systems 20 currently set to the stop mode. The storage battery system 20 is changed to the discharge mode. The EMS 60 executes the process of step S175 and then executes the process of step S176.

In step S176, in step S176, the electric power purchased from the grid power source S in the residential storage battery system (Nth residential storage battery system 2N in the present embodiment) arranged on the most upstream side is the minimum discharge threshold value a. Judge whether or not it is as follows. When the EMS 60 determines that the power purchased from the system power source S in the Nth residential storage battery system 2N is not equal to or less than the minimum discharge threshold value a (No in step S176), the process of step S174 is executed again.

When the power purchased from the grid power source S in the Nth residential storage battery system 2N is not equal to or less than the minimum discharge threshold a, at least among the residential storage battery systems 20 in which the discharge priority is set in step S173, Even if one or more residential storage battery systems 20 are discharging and power is discharged from all the residential storage battery systems 20 set in the discharge mode, the power consumption of each house H is covered. The case where it cannot be obtained (when the insufficient power is purchased from the system power supply S) is shown.

In such a case, the EMS 60 re-executes the process of step S174, and if possible (for the residential storage battery system 20 in which the discharge priority is set in step S173, the residential storage battery system 20 is set to the stop mode. (If the storage battery system 20 exists), increase the number of residential storage battery systems 20 set in the discharge mode so as to increase the amount of power from all the residential storage battery systems 20 set in the discharge mode. ..

Further, in step S176, when the EMS 60 determines that the power purchased from the system power source S in the Nth residential storage battery system 2N is equal to or less than the minimum discharge threshold value a (Yes in step S176), the process of step S177 is performed. Execute. When the power purchased from the system power source S in the Nth residential storage battery system 2N is equal to or less than the minimum discharge threshold a, at least among the residential storage battery systems 20 in which the discharge priority is set in step S173, When one or more residential storage battery systems 20 are discharging, and the power discharged from each residential storage battery system 20 set in the discharge mode, the power consumption of each house H can be covered. This indicates the case where the shortage of power is not purchased from the system power source S, or the case where all the residential storage battery systems 20 are not discharging.

Similarly, if No in step S161, Yes in step S162, Yes in step S164, Yes in step S172, or Yes in step S174, EMS60 is a step. The process of S177 is executed.

The case where No is set in step S161 means that the power consumption of each house H is covered (when the insufficient power is not purchased from the grid power source S), or all the residential storage battery systems 20. Shows the case where is not discharging. Further, the case of Yes in step S162 and the case of Yes in step S174 indicate the case where the residential storage battery system 20 set in the stop mode does not exist. Further, the case where Yes in step S164 means that the power consumption of each house H is covered (when the insufficient power is not purchased from the grid power source S), or all the residential storage battery systems 20. Shows the case where is not discharging. Further, the case of Yes in step S172 indicates a case where all the residential storage battery systems 20 cannot be discharged even in the discharge mode.

As described above, if it is Yes in step S176, if it is No in step S161, if it is Yes in step S162, if it is Yes in step S164, if it is Yes in step S172, or Yes in step S174. The case where the process of increasing the number of the residential storage battery systems 20 set in the discharge mode is not performed (cannot be performed or does not need to be performed) is shown.

As described above, in the process of operating the storage battery system according to the sixth embodiment, the EMS 60 executes the process of step S177 when the process of increasing the number of the residential storage battery systems 20 set in the discharge mode is not performed. ..

In step S177, the EMS 60 determines whether or not each residential storage battery system 20 set in the discharge mode has a residential storage battery system 20 that is on standby for discharge. When the EMS 60 determines that each residential storage battery system 20 set in the discharge mode has a residential storage battery system 20 that is on standby for discharge (Yes in step S177), the EMS 60 executes the process of step S178.

In step S178, the EMS 60 determines whether or not the remaining battery level of each residential storage battery system 20 set in the discharge mode is larger than the dischargeable threshold value b. When the EMS 60 determines that the remaining battery level of each residential storage battery system 20 set in the discharge mode is larger than the dischargeable threshold value b (Yes in step S178), the EMS 60 executes the process of step S179.

When the remaining battery level of each residential storage battery system 20 set in the discharge mode is larger than the dischargeable threshold b (Yes in step S178), all the residential storage battery systems 20 in the discharge standby state. The case where the remaining amount of the storage battery remains to the extent that it can be discharged (that is, the case where the discharge standby is performed because a surplus is generated with respect to the power consumption of each house H) is shown.

In step S179, the EMS 60 changes the residential storage battery system 20 having the lowest discharge priority among all the residential storage battery systems 20 set in the discharge mode to the stop mode. In this way, when there is a residential storage battery system 20 that is on standby for discharge due to a surplus in the power consumption of each house H, the EMS 60 is discharged not from the residential storage battery system 20 having a low discharge priority. Power is discharged from the residential storage battery system 20 having a high priority. The EMS 60 executes the process of step S179 and then executes the process of step S181.

Further, in step S178, in step S178, in the EMS 60, the remaining battery level of each residential storage battery system 20 set in the discharge mode is not larger than the dischargeable threshold value b (among the residential storage battery systems 20 set in the discharge mode). When it is determined (No in step S178), it is determined that the remaining battery level of at least one or more residential storage battery systems 20 is the dischargeable threshold value b or less), the process of step S180 is executed.

The remaining amount of the storage battery of each residential storage battery system 20 set in the discharge mode is not larger than the dischargeable threshold b (at least one of the residential storage battery systems 20 set in the discharge mode for residential use). When the remaining battery level of the storage battery system 20 is equal to or less than the dischargeable threshold b), the remaining battery level of at least one or more residential storage battery systems 20 among all the residential storage battery systems 20 on standby for discharge can be discharged. It shows a case where the remaining amount does not remain (that is, even if the power consumption of each house H cannot be covered, it is in a discharge standby because it cannot be discharged).

In step S180, the EMS 60 extracts the residential storage battery system 20 whose remaining storage battery level is equal to or less than the dischargeable threshold b from all the residential storage battery systems 20 set in the discharge mode, and each of the extracted residential storage battery systems 20. Change 20 to stop mode. In this way, among the residential storage battery systems 20 set in the discharge mode, the EMS 60 sets the residential storage battery system 20 in which the remaining amount of the storage battery is not enough to be discharged as the stop mode. The EMS 60 executes the process of step S180 and then executes the process of step S181.

In step S181, the EMS 60 determines whether or not all the residential storage battery systems 20 set in the discharge mode are discharged. When the EMS 60 determines that all the residential storage battery systems 20 set in the discharge mode are not discharged (No in step S181), the EMS 60 executes the process of step S178 again.

When all the residential storage battery systems 20 set in the discharge mode are not discharged (No in step S181), the discharge standby is performed among all the residential storage battery systems 20 set in the discharge mode. The case where there is a residential storage battery system 20, that is, the case where the power consumption of each house H is covered and the number of residential storage battery systems 20 more than necessary is set to the discharge mode is shown.

In such a case, the EMS 60 re-executes the process of step S178 to minimize the discharge from the residential storage battery system 20 having the lowest discharge priority, so that the residential storage battery system 20 having the lowest discharge priority 20 does not discharge as much as possible. To stop mode.

Further, in step S181, when the EMS 60 determines that all the residential storage battery systems 20 set in the discharge mode are discharged (Yes in step S181), the EMS 60 ends the processing of the storage battery system operation. The case where all the residential storage battery systems 20 set in the discharge mode are discharged indicates the case where the number of the residential storage battery systems 20 set in the discharge mode cannot be further reduced. ..

Further, in step S177, when the EMS 60 determines that there is no residential storage battery system 20 that is on standby for discharge among all the residential storage battery systems 20 set in the discharge mode (No in step S177), the storage battery system operates. End the process. In addition, among all the residential storage battery systems 20 set in the discharge mode, when there is no residential storage battery system 20 in the discharge standby, the number of the residential storage battery systems 20 set in the discharge mode is further reduced. It shows the case where it cannot be made to do.

As described above, in the processing of the storage battery system operation according to the sixth embodiment, the operation (discharge and discharge stop) of the residential storage battery system 20 is controlled, and the processing is different from the processing of the storage battery system operation according to the fifth embodiment. , Not only the determination of whether or not the power purchased from the grid power source S in the Nth residential storage battery system 2N is larger than the minimum discharge threshold a (step S161), but also the remaining storage battery level of each residential storage battery system 20 While finely adjusting the amount of discharge from the residential storage battery system 20 based on the determination of whether or not it is larger than the dischargeable threshold b (step S171), the amount of discharge in the plurality of residential storage battery systems 20 is biased (storage battery). It is possible to eliminate the bias of the remaining amount). In this way, by eliminating the bias caused in the amount of discharge in the plurality of residential storage battery systems 20, it is possible to more reliably equalize the charges that can be obtained among the plurality of houses H (residents).

In the process of operating the storage battery system according to the sixth embodiment, the processes of step S164, step S176, and step S181 are executed, but the same as step S124 in the process of operating the storage battery system according to the first embodiment. In addition, the process may be omitted (see the process of operating the storage battery system according to the second embodiment (another example of the first embodiment)).

As described above, in the power supply system 1 according to the present embodiment,
Multiple residential photovoltaic power generation systems 40 (power generation systems) that can generate power using natural energy,
It is provided corresponding to each of a plurality of residential photovoltaic power generation systems 40, can charge the electric power from the corresponding residential photovoltaic power generation system 40, can supply electric power to the residential H (load), and is related to operation. A plurality of residential storage battery systems 20 (storage battery systems) capable of executing a plurality of operation modes, and
EMS60 (control unit) for switching the operation mode of the residential storage battery system 20 and
Equipped with
The residential storage battery system 20
As the operation mode, it is possible to execute a discharge mode in which discharge is possible or a stop mode in which discharge is not possible according to the request of the house H (load).
The EMS60 (control unit)
The remaining amount of the storage battery of the residential storage battery system 20 is acquired, and a plurality of the plurality of the residential storage battery systems 20 are prioritized in descending order of the acquired remaining amount of the stored battery.
The residential storage battery system 20 having the highest priority is set to the discharge mode, and the other residential storage battery system 20 is set to the stop mode.

With such a configuration, it is possible to prevent the discharge or charge from being biased to a specific residential storage battery system 20 among the plurality of residential storage battery systems 20.
In this way, in order to prevent the discharge amount in the plurality of residential storage battery systems 20 from being biased, it is possible to equalize the charges that can be obtained among the plurality of houses H (residents). Further, in order to prevent the discharge amount of the plurality of residential storage battery systems 20 from being biased, it is possible to equalize the life (useful life) of the plurality of residential storage battery systems 20. Further, by preferentially discharging the residential storage battery system 20 having a large remaining amount of the storage battery, it becomes easy to secure free capacity in the residential storage battery system 20. This makes it easier to charge the surplus power and prevents the surplus power from being wasted.

Further, in the power supply system 1 according to the present embodiment,
A shared storage battery system 30 (insufficient power supply system) that supplies power to the house H (load) when the power from the residential storage battery system 20 in the discharge mode is insufficient for the request of the house H (load). )
The EMS60 (control unit)
When power is supplied from the shared storage battery system 30 (insufficient power supply system) to the house H (load).
Among the residential storage battery systems 20 in the stop mode, the residential storage battery system 20 having the highest priority is set to the discharge mode.

With such a configuration, it is possible to more effectively prevent the discharge or charge from being biased to a specific residential storage battery system 20 among the plurality of residential storage battery systems 20.

Further, in the power supply system 1 according to the present embodiment,
The plurality of residential storage battery systems 20 are connected to the residential H (load) rather than the shared storage battery system 30 (insufficient power supply system).

With such a configuration, it is possible to more effectively prevent the discharge or charge from being biased to a specific residential storage battery system 20 among the plurality of residential storage battery systems 20.

Further, in the power supply system 1 according to the present embodiment,
The plurality of residential storage battery systems 20 are owned by one of the residents (plurality of consumers) of the house H.
The shortage power supply system is shared by the residents (plurality of consumers) of the house H.

With such a configuration, by using a system shared by the residents of a plurality of houses H that supply electric power to the load, the discharge or charge is biased to a specific residential storage battery system 20 among the plurality of residential storage battery systems 20. It can be prevented more effectively.

The residential photovoltaic power generation system 40 is an embodiment of the power generation system.
The residential storage battery system 20 is an embodiment of the storage battery system.
Further, the shared storage battery system 30 is an embodiment of an insufficient power supply system.
Further, the house H is an embodiment of the load.
Further, the EMS 60 is an embodiment of the control unit.
In addition, the resident of the house H is an embodiment of the consumer.

Although one embodiment has been described above, the present invention is not limited to the above configuration, and various modifications can be made within the scope of the invention described in the claims.

For example, in the above embodiment, it is assumed that the electric power retailer collectively purchases electric power from the electric power company and the electric power purchased from the plurality of houses H is appropriately supplied (accommodated) between the plurality of houses H. It does not have to be purchased in bulk from the electric power company.

Further, although the residential photovoltaic power generation system 40 and the shared photovoltaic power generation system 50 are supposed to generate power by using sunlight, other natural energy is used in place of the residential photovoltaic power generation system 40 and the like. It is also possible to use a power generation system capable of generating power (for example, a wind power generation system or the like).

Further, it is not the EMS 60 that switches the eco mode, the discharge mode, and the stop mode of the residential storage battery system 20, but an appropriate control unit can be selected.

Further, the EMS 60 determines whether or not the current time is the set time A (set time B) in the time zone processing, but the specific values (time) of the set time A and the set time B are determined. Is not limited and can be set arbitrarily. Further, since the set time A (set time B) is for determining whether or not the residential photovoltaic power generation system 40 is irradiated with sunlight, it is appropriately changed according to the season (sunshine duration) and the like. You may.

Further, in the time zone processing, the EMS 60 determines whether or not the current time is the set time A (set time B) to determine whether or not the residential photovoltaic power generation system 40 is irradiated with sunlight. However, the determination (estimation) is not limited to this, and it is also possible to determine whether or not sunlight is being irradiated by detecting the amount of power generated by the residential photovoltaic power generation system 40. It is also possible to separately provide an illuminance meter to determine whether or not sunlight is being irradiated.

Further, in the above embodiment, one photovoltaic power generation system (residential photovoltaic power generation system 40 and shared photovoltaic power generation system 50) is used for one storage battery system (residential storage battery system 20 and shared storage battery system 30). The configuration to be provided (connected) is shown, but the present invention is not limited to this. For example, it is possible to configure a plurality of photovoltaic power generation systems to be connected to one storage battery system. It is also possible to configure a plurality of storage battery systems to be connected to one photovoltaic power generation system.

Further, the "remaining battery capacity" of the storage battery system (residential storage battery system 20 and shared storage battery system 30) in the above embodiment is not only the amount of electric power (kWh) charged in the storage battery system, but also the storage battery system. It may be the ratio (%) of the charged power to the capacity of. In this way, by prioritizing based on the ratio (%), it is possible to effectively suppress the occurrence of discharge and charge bias when a plurality of storage battery systems having different capacities are used.

1 Power supply system 20 Residential storage battery system 30 Shared storage battery system 40 Residential photovoltaic power generation system 50 Shared photovoltaic power generation system 60 EMS
H residential S system power supply

Claims (3)

Multiple power generation systems that can generate power using natural energy,
It is provided corresponding to each of the plurality of power generation systems, and is connected to a distribution line connecting the system power supply and the load so as to line up from the system power supply toward the load side to charge the power from the corresponding power generation system. possible and with which can supply power to the load, a plurality of battery storage system capable of executing a plurality of operating modes of the operation,
A control unit that switches the operation mode of the storage battery system, and
Equipped with
The storage battery system
It has a storage battery system sensor that detects the power immediately upstream of the connection point between the distribution line and the storage battery system, and as the operation mode , it meets the load request acquired from the detection result of the storage battery system sensor. It is possible to execute a discharge mode in which the corresponding power can be discharged at the discretion of the storage battery system , or a stop mode in which the corresponding power cannot be discharged.
The control unit
In addition to acquiring the remaining battery level of the storage battery system, a plurality of the storage battery systems are prioritized in descending order of the acquired remaining battery level.
Wherein the dischargeable electric power corresponding to a request of the load top-level storage battery system and with the discharging mode of priority to the judgment of the battery system of the top-level, the other storage battery system and the stop mode ,
Power supply system. The distribution line is provided with an insufficient power supply system connected to the system power supply side of the plurality of storage battery systems.
The insufficient power supply system
It has a sensor for the insufficient power supply system that detects the electric power on the immediate upstream side of the connection point between the distribution line and the insufficient power supply system, and the electric power from the storage battery system in the discharge mode responds to the load request. when insufficient, the to the load subjected supply power to the shortage is acquired by the detection result of the sensor the lack power supply system at the discretion of the missing power supply system,
The control unit
When power is supplied from the insufficient power supply system to the load,
Among the storage battery systems in the stop mode that do not include the storage battery system having the highest priority in the discharge mode, the storage battery system having the highest priority is set as the discharge mode.
The power supply system according to claim 1. The plurality of storage battery systems are owned by one of a plurality of consumers and
The shortage power supply system is shared by the plurality of consumers.
The power supply system according to claim 2.

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