JP2017221051A - Power supply system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a power supply system which can effectively prevent the deviation of discharge and charge to a particular power storage device among a plurality of power storage devices.SOLUTION: The power supply system includes: a plurality of photovoltaic power generation systems 40; a plurality of house storage battery systems corresponding to the photovoltaic power generation systems 40; and an EMS which switches over each operation mode of the house storage battery systems. As an operation mode, each house storage battery system can execute a discharge mode which can discharge according to a request from a house, and a suspension mode which disables to discharge. The EMS acquires a storage battery residual amount of each house storage battery system to set the priority of the plurality of house storage battery systems in order from the largest acquired storage battery residual amount to the smallest. The EMS then sets a house storage battery system of the highest priority to be the discharge mode, whereas sets other house storage battery systems to be the suspension mode.SELECTED DRAWING: Figure 4

Description

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

  Conventionally, the technique of the electric power supply system which comprises the some storage battery system which can charge / discharge electric power is well-known. For example, as described in Patent Document 1.

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

JP, 2006-73009, A

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

  The present invention has been made in view of the situation as described above, and the problem to be solved is a power supply capable of preventing discharge and charging from being biased to a specific storage battery system among a plurality of storage battery systems. A system is provided.

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

  In other words, 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 other, and the power from the corresponding power generation systems can be charged and supplied to the load. And a plurality of storage battery systems capable of executing a plurality of operation modes related to operation, and a control unit that switches the operation mode of the storage battery system, wherein the storage battery system responds to the load request as the operation mode. A discharge mode that enables discharge or a stop mode that disables discharge can be executed, and the control unit acquires the storage battery remaining amount of the storage battery system, and in order of increasing the acquired storage battery remaining amount. Prioritizing a plurality of the storage battery systems, the storage battery system of the highest priority in the priority order as the discharge mode, Of the battery system is intended to be the stop mode.

A power supply system that supplies power to the load when power from the storage battery system in the discharge mode is insufficient with respect to the demand of the load; and the control unit includes the power supply system from the power shortage system. When electric power is supplied to a load, the storage battery system having the highest priority among the storage battery systems in the stop mode may be set to the discharge mode.
With such a configuration, it is possible to more effectively prevent the discharge and charging from being biased toward a specific storage battery system among the plurality of storage battery systems.

The plurality of storage battery systems may be connected to the load side with respect to the insufficient power supply system.
With such a configuration, it is possible to more effectively prevent the discharge and charging from being biased toward a specific storage battery system among the plurality of storage battery systems.

The plurality of storage battery systems may be owned by any one of a 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 and charging from being biased to a specific storage battery system among a plurality of storage battery systems, using a system shared by a plurality of consumers supplying power to a load. Can do.

  As effects of the present invention, the following effects can be obtained.

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

The block diagram which showed the structure of the electric power supply system which concerns on 1st embodiment. Similarly, the block diagram which showed an example of the supply mode of the electric power when normal mode is performed. Similarly, the flowchart which showed the time slot | zone process by EMS when a uniform mode is performed. Similarly, the flowchart which showed the process of the preset by EMS when a uniform mode is performed. Similarly, the figure which showed an example of the set discharge priority. Similarly, the flowchart which showed the process of the storage battery system operation | movement which concerns on 1st embodiment by EMS when a uniform mode is performed. Similarly, the block diagram which showed an example of the supply mode of the electric power when the equal mode is performed. Similarly, the flowchart which showed the process of the storage battery system operation | movement which concerns on 2nd embodiment by EMS when a uniform mode is performed. Similarly, the flowchart which showed the process of the storage battery system operation | movement which concerns on 3rd embodiment by EMS when a uniform mode is performed. Similarly, the flowchart which showed the process of the storage battery system operation | movement which concerns on 4th embodiment by EMS when a uniform mode is performed. The block diagram which showed the structure of the electric power supply system which concerns on 2nd embodiment. Similarly, the flowchart which showed the process of the storage battery system operation | movement which concerns on 5th embodiment by EMS when a uniform mode is performed. Similarly, the flowchart which showed the process of the storage battery system operation | movement which concerns on 6th embodiment by EMS when a uniform mode is performed. Similarly, the flowchart which showed the continuation of FIG.

  Below, the electric power supply system 1 which concerns on 1st embodiment is demonstrated using FIG.

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

  The power supply system 1 appropriately supplies (accommodates) power, etc., collectively purchased from a power company by a power retailer among a plurality of houses H (first house H1, second house H2,..., Nth house HN). ) System. The power supply system 1 mainly includes a sensor unit 10, a plurality of residential storage battery systems 20 (a first residential storage battery system 21, a second residential storage battery system 22,..., An Nth residential storage battery system 2N), and a shared storage battery system. 30, a plurality of residential solar power generation systems 40 (first residential solar power generation system 41, second residential solar power generation system 42,..., Nth residential solar power generation system 4N), shared solar power generation System 50 and EMS 60 are provided.

  The plurality of houses H (first house H1, second house H2,..., Nth house HN) are buildings where people live. Each house H is provided with appropriate electrical products and consumes electric power.

  Each house H is connected to a system 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. Connected.

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

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

  Specifically, the shared sensor 10T is electrically connected to a shared storage battery system 30 described later. Moreover, the 1st sensor 11 is electrically connected with the storage battery system 21 for 1st houses mentioned later. Moreover, the 2nd sensor 12 is electrically connected with the storage battery system 22 for 2nd houses mentioned later. The Nth sensor 1N is electrically connected to an Nth residential storage battery system 2N described later.

  Further, the common 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 common sensor 10T, the first sensor 11, the second sensor 12,..., The Nth sensor 1N are respectively connected to a common connection point PT, a first connection point P1, and a second connection in the distribution line L. The points P2,... Are arranged immediately upstream of the Nth 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) include a plurality of residential solar power generation systems 40 (from Specifically, this is a system for appropriately charging power from a corresponding residential solar power generation system 40) among a plurality of residential solar power generation systems 40 and discharging the power as appropriate. Each residential storage battery system 20 includes a chargeable / dischargeable storage battery, a power conditioner for controlling charge / discharge of the storage battery, and the like. Each home storage battery system 20 is provided so as to correspond to a predetermined home H (one home storage battery system 20 is provided for one home H). Each residential storage battery system 20 is owned by the predetermined house H (resident of the house H).

  In addition, each residential storage battery system 20 is connected to a midway portion 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 have a first connection point P1, a second connection point P2, and a second connection point P2, 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 houses) to the upstream side (system power supply S side). Are arranged.

  Each residential storage battery system 20 includes a plurality of residential solar power generation systems 40 (more specifically, a corresponding residential solar power generation system 40 among the plurality of residential solar power generation systems 40). The generated power is configured to be charged. The electric power generated by the residential solar power generation system 40 (particularly surplus electric power) is charged in each of the storage battery systems 20 for residential use, and the charged electric power is discharged as necessary. Can be reduced, and self-sufficiency of power in the residential area T can be promoted.

  Moreover, each storage battery system 20 for houses is electrically connected with the sensor (1st sensor 11, 2nd sensor 12, ..., Nth sensor 1N) of the corresponding sensor part 10 as mentioned above. Each residential storage battery system 20 is configured such that a signal output from a sensor of the corresponding sensor unit 10 is input and a detection result of the sensor can be acquired based on the input signal. Each residential storage battery system 20 can perform load following operation that adjusts the amount of electric power to be discharged (output) based on the detection result of the sensor of the corresponding sensor unit 10.

  Each residential storage battery system 20 has a plurality of modes as modes relating to operation. The plurality of modes include “eco mode”, “discharge mode”, and “stop mode”. The “eco mode” is a mode in which power from the residential solar power generation system 40 is preferentially used in the house H, and surplus power in the residential solar power generation system 40 is appropriately charged and discharged. In addition, the discharge mode is a state in which each storage battery system 20 can be operatively discharged (regardless of whether or not the remaining amount of storage battery remains to the extent that discharge is possible) according to the power consumption of each house H. Is the mode. The stop mode is a mode in which each residential storage battery system 20 is in a state where it cannot be discharged in terms of operation.

  Moreover, each storage battery system 20 for houses is comprised so that detection of the electric energy (henceforth a "storage battery remaining amount") charged by itself is possible.

  The shared storage battery system 30 is a system for appropriately charging power from a shared solar power generation system 50 described later and discharging the power as appropriate. The shared storage battery system 30 includes a chargeable / dischargeable storage battery, a power conditioner that controls charge / discharge 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 a power retailer.

  Further, the shared storage battery system 30 is connected to a midway portion 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 common connection point PT is arranged on the upstream side (system power supply S side) of the distribution line L from the Nth connection point PN.

  Moreover, 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 to receive a signal output from the shared sensor 10T and to obtain a detection result of the shared sensor 10T based on the input signal. The shared storage battery system 30 can perform a load following operation that adjusts the amount of electric power to be discharged (output) based on the detection result of the shared sensor 10T.

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

  Each residential solar power generation system 40 is connected to the residential storage battery system 20 of the house H that is owned. Specifically, the solar power generation system 41 for the first house, the solar power generation system 42 for the second house,... The storage battery system 22 for houses is connected to the N-th storage battery system 2N. Thus, each residential storage battery system 20 and each residential solar power generation system 40 are provided so as to correspond.

  Each residential solar power generation system 40 is configured to be able to supply electric power to an owned house H (load). Each house H (resident of the house H) can use the electric power generated in the residential photovoltaic power generation system 40 as appropriate. Moreover, each photovoltaic power generation system 40 for residential | homes uses the electric power for surplus (surplus electric power) which was not used by the house H owned among the generated electric power to the residential storage battery system 20 of the said house H. And the storage battery system 20 for home can be charged.

  The shared solar power generation system 50 is a system for generating power using sunlight. The shared solar power generation system 50 includes a solar battery module that is formed into a plate shape by combining solar batteries (cells), a power conditioner that adjusts power from the solar battery 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 solar power generation system 50 is owned by a power retailer.

  The shared solar power generation system 50 is connected to the shared storage battery system 30. The shared solar power generation system 50 can supply the generated power to the shared storage battery system 30 and charge the shared storage battery system 30.

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

  In addition, the EMS 60 is electrically connected to the shared storage battery system 30 and each of the residential storage battery systems 20. The EMS 60 outputs a predetermined signal to the shared storage battery system 30 and each of the residential storage battery systems 20, and can control the operation of the shared storage battery system 30 and each of the residential storage battery systems 20. The EMS 60 is configured such that a predetermined signal can be input from the shared storage battery system 30 and each of the residential storage battery systems 20.

  In this way, the EMS 60 can acquire information regarding the operations of the shared storage battery system 30 and each of the residential storage battery systems 20. Specifically, the EMS 60 can acquire the remaining storage battery capacity of each residential storage battery system 20. Moreover, EMS60 can acquire the information of whether the common storage battery system 30 and the storage battery system 20 for houses are discharging (it is standby for discharge).

  The EMS 60 is configured to be able to execute a plurality of modes as modes relating to the operation of the power supply system 1. The plurality of modes include “normal mode” and “equal mode”. The normal mode is a mode that allows a deviation in discharge amount in the plurality of residential storage battery systems 20. The uniform mode is a mode that suppresses the uneven discharge amount (aiming to equalize the discharge amount) in the plurality of residential storage battery systems 20. Note that whether the normal mode or the equal mode is executed is appropriately selected by, for example, an electric power retailer.

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

  The electric power retailer sells the electric power collectively purchased from the electric power company (system power supply S) to the respective houses H according to the request from each house H as appropriate. A resident of each house H can use the power purchased from the power company. In addition, the power retailer purchases the electric power discharged from each storage battery system 20 and appropriately sells the electric power to each house H in response to a request from each house H. The price of electric power sold and sold by electric power retailers is set as appropriate.

  Thus, the power retailer can make a profit by buying and selling power. Moreover, the resident of each house H can also obtain a profit by selling the electric power (namely, surplus electric power) of the storage battery system 20 for houses to an electric power retailer.

  Below, the outline | summary of the supply (accommodation) aspect of electric power in the case of performing normal mode is demonstrated.

  The electric power from the system 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 among the plurality of storage battery systems (the 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. A follow-up operation is performed to discharge a predetermined amount of power. Thus, the electric power discharged from the first storage battery system 21 is supplied to each house H. In addition, if electric power is discharged from the storage battery system 21 for 1st houses, the electric energy from the system power supply S will reduce.

  Further, when the power consumption of each house H cannot be covered only by the power from the first house storage battery system 21, the insufficient power is supplied from the system power source S to each house H. That is, power from the system power supply S (power shortage) is supplied to each house H via the distribution line L. In this case, among the plurality of storage battery systems (the shared storage battery system 30 and the plurality of residential storage battery systems 20), the second residential storage battery system 22 arranged on the 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 to discharge a predetermined amount of power. Thus, the electric power discharged from the storage battery system 22 for second houses is supplied to each house H. In addition, if electric power is discharged from the storage battery system 22 for 2nd houses, the electric energy from the system power supply S will further reduce.

  Thus, in the case where the normal mode is executed, when the power consumption of each house H cannot be covered, the house arranged one upstream from the storage battery system 20 for house (where the discharge is started). The operation of starting discharging from the storage battery system 20 is repeatedly performed. Thus, with respect to the power consumption of each house H, among the plurality of storage battery systems, discharge is started sequentially from the storage battery system arranged on the downstream side to the storage battery system arranged on the upstream side.

  In addition, even if electric power is discharged from the Nth residential storage battery system 2N, when the power consumption of each house H cannot be covered, the electric power from the shared storage battery system 30 is discharged. And even if electric power is discharged from the shared storage battery system 30, when the power consumption of each house H cannot be covered, the electric power which is insufficient from the system power supply S is purchased (the electric power purchased from the system power supply S is , Supplied to each house H).

  Thus, in the power supply system 1, when the normal mode is executed, the electric power discharged from each residential storage battery system 20 is not limited to the resident (house H) that owns each residential storage battery system 20. Will also be supplied to other residents (house H). In other words, surplus power of each residential solar power generation system 40 charged in each residential storage battery system 20 can be appropriately accommodated between the plurality of houses H.

  In addition, the electric power discharged from each storage battery system 20 as mentioned above is the electric power generated in the house H (residential photovoltaic power generation system 40) which owns each said storage battery system 20 for houses. Since the electric power discharged from each storage battery system 20 for homes is once purchased by an electric power retailer, the charge corresponding to the electric power is paid to each home H (resident).

  Here, when the normal mode is executed, a problem may arise 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 battery is disposed upstream from the residential storage battery system 20 disposed downstream. Since the discharge is sequentially started to the residential storage battery system 20, the amount of discharge is larger in the residential storage battery system 20 arranged on the downstream side than on the upstream side. Therefore, the charge (charge paid from the electric power retailer to the resident of the house H) due to the interchange of electric power among the plurality of houses H is obtained from the storage battery system 20 for the house arranged downstream from the upstream side. Many residents will own it.

  For example, as shown in FIG. 2, when the power consumption of each house H is covered only by the electric power discharged from the first residential storage battery system 21 arranged on the most downstream side, other residential storage battery systems No power is discharged from 20 (second housing storage battery system 22 or Nth housing storage battery system 2N, etc.). In such a case, only the resident of the first house H1 who owns the first battery storage system 21 obtains the charge for the interchange of power among the plurality of houses H.

  As described above, when the normal mode is executed, the amount of discharge in the plurality of residential storage battery systems 20 is biased, and thus the charges that can be obtained among the plurality of houses H (residents) are uneven. there were. Moreover, since the discharge amount in the plurality of residential storage battery systems 20 is biased, the life (lifetime) in the plurality of residential storage battery systems 20 is uneven, which is a problem. In addition, when there is a residential storage battery system 20 that is not fully discharged due to an uneven discharge amount in the plurality of residential storage battery systems 20, the residential storage battery system 20 cannot charge surplus power. This is a problem in that the generated power may be wasted.

  Therefore, in the power supply system 1, the equal mode can be executed in order to solve the problems as described above. In the equal mode, correction (in order to suppress the bias of the discharge amount in the plurality of residential storage battery systems 20) based on the operation (load following operation) of each residential storage battery system 20 in the normal mode is performed. A process such as setting a predetermined discharge priority order for the discharge is performed.

  Hereinafter, the processing of the EMS 60 when the uniform mode is executed will be described.

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

  In the time zone in which the solar power generation system 40 is irradiated with sunlight, the power (especially surplus power) generated by the residential solar power generation system 40 is charged into the storage battery system 20 for effective use. It is desirable to plan. Therefore, the EMS 60 performs processing (time zone processing) for switching the mode of the residential storage battery system 20 to the “eco mode” in a time zone in which the solar photovoltaic power generation system 40 is considered to be irradiated with sunlight.

  Below, the time zone process by EMS60 is demonstrated concretely using 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 solar 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 the residential solar power generation system 40 can generate power. The set time A is stored (set) in the EMS 60 in advance. As the set time A, the daytime is mainly set. For example, the set time A is set to “7 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 of the residential storage battery systems 20 to the eco mode. Each residential storage battery system 20 set in the eco mode is charged with surplus power from the residential solar power generation system 40 of each house H.

  In addition, in the state (namely, setting time A) in which each storage battery system 20 for houses is set to eco mode, each house H uses the electric power generated in the solar power generation system 40 for houses which each has. In addition, when the electric power alone is insufficient, electric power charged in each residential storage battery system 20 or electric power from the system power source S is used. Thus, in the eco mode, the power generated by each residential solar power generation system 40 is preferentially used.

  In step S101, when the EMS 60 determines that the current time is not the set time A (No in step S101), the process of step S103 is executed.

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 the residential solar power generation system 40 is considered not to be irradiated with sunlight. That is, the set time B is a time when it is considered that power generation by the residential solar power generation system 40 is impossible. The set time B is stored (set) in the EMS 60 in advance. As the set time B, the night time 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 pre-setting processing. The specific contents of the preset process will be described later.
The EMS 60 executes the process of step S105 after executing the process of step S104.

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

  Thus, after executing the processing of step S102 or step S105, and when determining that the current time is not the set time B in step S103, the EMS 60 ends the time zone processing.

  Next, the pre-setting process (step S104) by the EMS 60 will be described.

  In the pre-setting process, the EMS 60 sets the discharge priority order and the mode related to the operation of each residential storage battery system 20. Moreover, in the process of storage battery system operation | movement, EMS60 operates each storage battery system 20 for houses concretely based on the setting performed by the process of a preset setting. The discharge priority order is a criterion for determining which of the residential storage battery systems 20 is to be discharged preferentially.

  Hereinafter, the pre-setting process by the EMS 60 will be specifically described with reference to FIG.

  In step S <b> 111, the EMS 60 acquires the remaining storage battery capacity of each residential storage battery system 20. The EMS 60 executes the process of step S112 after executing the process of step S111.

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

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

  The EMS 60 executes the process of step S113 after executing the process of step S112.

  In step S113, the EMS 60 sets the top (first) residential storage battery system 20 to the discharge mode based on the discharge priority set in step S112, and the other (second,..., Nth The residential storage battery system 20 of the -1st place and the Nth place) is set 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. (Second housing storage battery system 22, first housing storage battery system 21, etc.) are set to the stop mode.

  Thus, the EMS 60 terminates the pre-setting process after executing the process of step S113.

  Next, the process of the storage battery system operation | movement which concerns on 1st embodiment by EMS60 is demonstrated.

  In the storage battery system operation process, the EMS 60 specifically operates each residential storage battery system 20 based on the setting performed in the preset process.

  Below, the process of the storage battery system operation | movement which concerns on 1st embodiment by EMS60 is demonstrated concretely using FIG.

  In step S121, the EMS 60 determines whether or not the shared storage battery system 30 is discharged. If EMS60 judges that the shared storage battery system 30 is discharging (it is Yes at step S121), the process of step S122 will be performed. In addition, the case where the shared storage battery system 30 is discharging means that each house H even if electric power is discharged from all the storage battery systems 20 for residential use set in the discharge mode (that is, in a state in which it can be discharged in an operational manner). It shows the case where the power consumption of can not be 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 with 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 with the lowest discharge priority is not set to the discharge mode indicates a 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 with the highest discharge priority among the residential storage battery systems 20 currently set to the stop mode to the discharge mode. Thus, the EMS 60 increases the number of the 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. EMS60 performs the process of step S124, after performing the process of step S123.

  Thus, even when power is discharged from all the storage battery systems 20 for residential use set to the discharge mode, the power consumption of each home H cannot be covered (Yes in step S121), and the stop mode is set. If the residential storage battery system 20 is present (No in step S122), by increasing the number of residential storage battery systems 20 set in the discharge mode, all the houses set in the discharge mode The amount of electric 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 EMS 60 determines that shared storage battery system 30 is not in standby for discharge (No in step S124), it executes the process of step S122 again. In addition, the case where the shared storage battery system 30 is not in the standby state for discharge means that the power consumption of each house H cannot be covered even if power is discharged from all the storage battery systems 20 set in the discharge mode (the shared storage battery system). 30 also shows the case where electric power is discharged.

  In such a case, the EMS 60 performs the process of step S122 again, and if possible (if there is a residential storage battery system 20 set in the stop mode), all of those set in 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 power from the residential storage battery system 20.

  In step S124, when the EMS 60 determines that the shared storage battery system 30 is on standby for discharge (Yes in step S124), the process of the storage battery system operation ends. In addition, the case where the shared storage battery system 30 is in the standby state for discharge is a case where the power consumed by each house H is covered by the power discharged from each of the storage battery systems 20 for houses set in the discharge mode (the shared storage battery system 30 Shows the case where there is no need to discharge).

  In Step S122, when EMS 60 determines that the storage battery system 20 for residential use having the lowest discharge priority is set to the discharge mode (Yes in Step S122), the process of the storage battery system operation ends. The case where the residential storage battery system 20 with the lowest discharge priority is set to the discharge mode indicates a 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 EMS 60 increases the amount of power from all the residential storage battery systems 20 set in the discharge mode. I can't. Thus, when the residential storage battery system 20 with the lowest discharge priority is set to the discharge mode, the shortage of power is purchased from the system power source S, and the purchased power is sent to each house H. Supplied.

  In step S121, when EMS 60 determines that shared storage battery system 30 is not discharged (No in step S121), the process of the storage battery system operation is terminated. The case where the shared storage battery system 30 is not discharged means that the power consumed by each house H is covered by the power discharged from each house storage battery system 20 set in the discharge mode (the shared storage battery system 30). Shows the case where there is no need 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 deviation of the discharge amount in the plurality of residential storage battery systems 20 (of the remaining battery capacity). (Bias) can be resolved (discharge can be effectively prevented from being biased to a specific residential storage battery system 20). Thus, by eliminating the bias generated in the discharge amount in the plurality of storage battery systems 20 for homes, it is possible to equalize the charges that can be obtained among the plurality of homes H (residents). Hereinafter, a specific description will be given with reference to FIG.

  Here, FIG. 7 shows a power supply mode when the equal mode (processing of the storage battery system operation) is executed in the example of the discharge priority order 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.

  And if only the electric power discharged from the Nth residential storage battery system 2N cannot cover the power consumption of each house H (Yes in step S121), the residential storage battery system currently set to the stop mode Among the 20, the storage battery system 20 for homes with 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 thus all the residential storage battery systems 20 set in the discharge mode (the Nth residential storage battery system 2N and the above-mentioned The amount of power from the (N-1th storage battery system for home) is increased.

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

  Moreover, the bias of the charging / discharging frequency in the plurality of residential storage battery systems 20 can also be resolved by eliminating the bias generated in the discharge amount in the plurality of residential storage battery systems 20. In this way, since the number of times of charging / discharging in the plurality of residential storage battery systems 20 can be equalized, the life (service life) of the plurality of residential storage battery systems 20 can be equalized.

  Moreover, it becomes easy to ensure an empty capacity | capacitance in the said storage battery system 20 for houses by performing discharge preferentially from the storage battery system 20 for houses with much residual storage battery. Thereby, it becomes easy to avoid a situation where the electric power generated by the residential solar power generation system 40 cannot be charged in the residential storage battery system 20 (there is no free capacity). Therefore, it is possible to prevent the power generated by the residential solar power generation system 40 from being wasted.

  Next, the process of the storage battery system operation | movement which concerns on 2nd embodiment (another example of 1st embodiment) by EMS60 is demonstrated using FIG.

  In addition, in the process of the storage battery system operation | movement which concerns on 2nd embodiment, a point different from the process of the storage battery system operation | movement which concerns on 1st embodiment is a point without the process of step S124. Specifically, after executing the process of step S123, the EMS 60 once ends the process of the storage battery system operation, and after a certain period of time has elapsed, starts the process of the storage battery system operation from step S121 again.

  Thus, for example, when 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 in the stop mode exists. If there is (No in step S122), the amount of power 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. (Step S123).

  Further, for example, when the EMS 60 determines that the shared storage battery system 30 is not discharged after the process of step S123 is executed (No in step S121), the EMS 60 is discharged from each residential storage battery system 20 set in the discharge mode. Because the power consumption of each house H is covered by the power (since the shared storage battery system 30 does not need to be discharged), the storage battery system operation process is temporarily terminated.

  Thus, by the process of the storage battery system operation according to the second embodiment, similarly to the process of the storage battery system operation according to the first embodiment, by controlling the operation (discharge) of the residential storage battery system 20, a plurality of It is possible to eliminate the uneven discharge amount (unbalance of the remaining amount of storage battery) in the residential storage battery system 20. Thus, by eliminating the bias generated in the discharge amount in the plurality of storage battery systems 20 for homes, it is possible to equalize the charges that can be obtained among the plurality of homes H (residents).

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

  In addition, in the process of the storage battery system operation | movement which concerns on 3rd embodiment, a point different from the process of the storage battery system operation | movement which concerns on 1st embodiment is a point which the process of step S131 to step S134 was added. Hereinafter, for the sake of convenience, the storage battery system operation process according to the third embodiment will be described with respect to differences from the storage battery system operation process according to the first embodiment (the process from step S131 to step S134). Description of the same points as the processing of the storage battery system operation (the processing from step S121 to step 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 greater than a predetermined minimum discharge threshold 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 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 power set by the regulations of the electric power company to purchase from the system power source S when at least one residential storage battery system 20 is discharging. Yes, for example 200W. That is, in this embodiment, the case where the electric 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 residential storage battery system 20 is discharging. And even if power is discharged from all the storage battery systems 20 for homes set to discharge mode, the power consumption of each house H cannot be covered (the power shortage is purchased from the system power supply S). 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 contents of this process are the same as in step S122. If the EMS 60 determines that the residential storage battery system 20 with 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 contents of this process are the same as in step S123. The EMS 60 executes the process of step S134 after executing the process of step S133.

  Thus, even if power is discharged from all the storage battery systems 20 for residential use set to discharge mode, it is a case where the power consumption of each house H cannot be covered (Yes in step S131), and is set to stop mode. If the residential storage battery system 20 is present (No in step S132), by increasing the number of residential storage battery systems 20 set to the discharge mode, all the houses set to the discharge mode It is possible to increase the amount of power from the storage battery system 20 (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 lower than the minimum discharge threshold 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 less than the minimum discharge threshold a (No in step S134), the process of step S132 is executed again. Note that the case where the electric power purchased from the grid power source S in the shared storage battery system 30 is not less than the minimum discharge threshold a is that each house even if the electric power is discharged from all the residential storage battery systems 20 set in the discharge mode. The case where the power consumption of H cannot be covered (when the shared storage battery system 30 is also discharging power) is shown.

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

  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 lower than the minimum discharge threshold a (Yes in step S134), the processing of the storage battery system operation ends. The case where the electric power purchased from the system power source S in the shared storage battery system 30 is equal to or lower than the minimum discharge threshold a is a case where at least one residential storage battery system 20 is discharging, and In the case where the electric power discharged from each storage battery system 20 set in the discharge mode covers the power consumption of each house H (when the insufficient power is not purchased from the system power source S), Or the case where all the storage battery systems 20 for houses are not discharging is shown.

  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 similar to the case of Yes in Step S122. Ends system operation processing.

  Thus, among the processing of the storage battery system operation according to the third embodiment, the processing of the storage battery system operation according to the first embodiment (processing from step S121 to step S124) is performed by the processing from step S131 to step S134. Similarly, by controlling the operation (discharge) of the residential storage battery system 20, it is possible to eliminate the uneven discharge amount (unbalance of the remaining amount of storage battery) in the plurality of residential storage battery systems 20. Thus, by eliminating the bias generated in the discharge amount in the plurality of storage battery systems 20 for homes, it is possible to equalize the charges that can be obtained among the plurality of homes H (residents).

  In step S131, when the EMS 60 determines that 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 (No in step S131), the EMS 60 executes the process of step S121. In addition, 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 a case where at least one residential storage battery system 20 is discharging, In addition, whether the power consumed by each house H is covered by the power discharged from each residential storage battery system 20 set to the discharge mode (when the insufficient power is not purchased from the system power supply S) Or the case where all the storage battery systems 20 for houses are not discharging is shown.

  Thus, in step S121 to step S124, the EMS 60 executes the same process as the process of the storage battery system operation according to the first embodiment. That is, among the processing of the storage battery system operation according to the third embodiment, the processing (discharge) of the residential storage battery system 20 is performed by the processing from step S121 to step S124 as in the processing of the storage battery system operation according to the first embodiment. ) Is controlled, it is possible to eliminate the uneven discharge amount (unbalance of the remaining amount of storage battery) in the plurality of residential storage battery systems 20. Thus, by eliminating the bias generated in the discharge amount in the plurality of storage battery systems 20 for homes, it is possible to equalize the charges that can be obtained among the plurality of homes H (residents).

  Thus, in the process 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 judgments of whether or not the shared storage battery system 30 is discharging (step S121), the bias generated in the discharge amounts in the plurality of residential storage battery systems 20 is eliminated. In other words, even if one of the two determinations is not accurately performed for some reason, the deviation of the discharge amount in the plurality of residential storage battery systems 20 is determined based on the remaining one determination. Since cancellation can be achieved, equalization of charges that can be obtained among a plurality of houses H (residents) can be more reliably achieved.

  In addition, in the process of the storage battery system operation | movement which concerns on 3rd embodiment, although the process of step S134 is performed, the said process is abbreviate | omitted similarly to step S124 in the process of the storage battery system operation | movement which concerns on 1st embodiment. It is also possible (see processing of storage battery system operation according to the second embodiment (another example of the first embodiment)).

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

  In addition, in the process of the storage battery system operation | movement which concerns on 4th embodiment, a point different from the process of the storage battery system operation | movement which concerns on 1st embodiment is a point which the process of step S141 to step S143 was added. Hereinafter, for the sake of convenience, in the processing of the storage battery system operation according to the fourth embodiment, points different from the processing of the storage battery system operation according to the first embodiment (the processing from step S141 to step S143) will be described, and the first embodiment will be described. Description of the same points as the processing of the storage battery system operation (the processing from step S121 to step 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.

  In addition, the case where it is No in step S121 and the case where it is Yes in step S124 indicate a case where the power consumption of each house H is covered (when the shared storage battery system 30 does not need to be discharged). . Moreover, the case where it is Yes in step S122 has shown the case where the storage battery system 20 for houses set to the stop mode does not exist. Thus, when it is No at Step S121, when it is Yes at Step S122, or when it is Yes at Step S124, the process of increasing the number of the storage battery systems 20 for residential use set to the discharge mode is performed. It shows the case where it is not performed (cannot be performed or does not need to be performed).

  Thus, in the process of the storage battery system operation according to the fourth embodiment, when the EMS 60 does not perform the process of increasing the number of the residential storage battery systems 20 set to the discharge mode, the process of step S141 is executed.

  In step S141, the EMS 60 determines whether each residential storage battery system 20 set to the discharge mode includes the residential storage battery system 20 that is in a standby state for discharge. When the EMS 60 determines that each of the residential storage battery systems 20 set to the discharge mode has the residential storage battery system 20 that is in the standby state for discharge (Yes in Step S141), the process of Step S142 is executed. In addition, the case where there is a residential storage battery system 20 that is in standby for discharge in each residential storage battery system 20 set in the discharge mode means that the power consumption of each residential H is covered and an excessive number of residential storage batteries is 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 to the discharge mode to the stop mode. In this way, the EMS 60 reduces the number of the residential storage battery systems 20 set to the discharge mode and prevents the discharge from the residential storage battery system 20 having a low discharge priority as much as possible. The EMS 60 executes the process of step S143 after executing the process of step S142.

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

  In addition, when all the storage battery systems 20 for homes set to discharge mode are not discharging (it is No at step S143), it is standby for discharge among all the storage battery systems 20 for homes set to discharge mode. The case where the storage battery system 20 for houses is present, that is, the case where the power consumption of each house H is covered and the number of the storage battery systems 20 for housing more than necessary is set to the discharge mode is shown.

  In such a case, the EMS 60 performs the process of step S142 again, so that the residential storage battery system 20 with the lowest discharge priority is prevented so as not to discharge as much as possible from the residential storage battery system 20 with the lowest discharge priority. Change to stop mode.

  In Step S143, if EMS60 judges that all the storage battery systems 20 for houses set to discharge mode are discharging (it is Yes at Step S143), processing of a storage battery system operation will be ended. The case where all the residential storage battery systems 20 set in the discharge mode are discharged indicates a case where the number of the residential storage battery systems 20 set in the discharge mode cannot be further reduced. .

  In Step S141, if EMS60 judges that each storage battery system 20 set as discharge mode does not have residential storage battery system 20 which is a standby for discharge (it is No at Step S141), processing of storage battery system operation will be carried out. finish. In addition, in the case where there is no residential storage battery system 20 that is in standby for discharge in each residential storage battery system 20 set in the discharge mode, the number of residential storage battery systems 20 set in the discharge mode is further reduced. It shows the case that can not be.

  Thus, by controlling the operation (discharge and discharge stop) of the residential storage battery system 20 by the process of the storage battery system operation according to the fourth embodiment, for example, than the process 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 uneven discharge amount (unbalance of the remaining amount of storage battery) in the plurality of residential storage battery systems 20. Thus, by eliminating the bias generated in the discharge amount in the plurality of storage battery systems 20 for homes, it is possible to more reliably achieve equalization of charges that can be obtained among the plurality of homes H (residents).

  In addition, in the process of the storage battery system operation | movement which concerns on 4th embodiment, although the process of step S143 is performed, the said process is abbreviate | omitted similarly to step S124 in the process of the storage battery system operation | movement which concerns on 1st embodiment. It is also possible (see processing of storage battery system operation according to the second embodiment (another example of the first embodiment)).

  Below, the electric power supply system 200 which concerns on 2nd embodiment is demonstrated using 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 that the shared storage battery system 30, the shared solar power generation system 50, and the sensor unit 10 are different. The common sensor 10T is not provided.

  In such a power supply system 200 as well, as in the power supply system 1, the equal mode can be executed in order to solve the problem as described above. In addition, when the uniform mode is executed, the EMS 60 performs time zone processing, and performs preset processing and storage battery system operation processing therein. In the power supply system 200, the pre-setting process performed by the EMS 60 when the uniform mode is executed is the same as that of the power supply system 1, and thus the description thereof is omitted.

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

  In step S161, the EMS 60 determines that the power purchased from the system power source S in the residential storage battery system (in the present embodiment, the Nth residential storage battery system 2N) disposed on the most upstream side is the lowest discharge threshold a. It is judged whether it is larger 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 a (Yes in step S161), the EMS 60 executes the process of step S162.

  The case where 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 is a case where at least one or more residential storage battery systems 20 are discharging. In addition, even if power is discharged from all the storage battery systems 20 for residential use set to the discharge mode, the power consumption of each house H is not covered (when the power for the shortage is purchased from the system power supply S) ).

  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 contents of this process are the same as in step S122. When the EMS 60 determines that the residential storage battery system 20 with 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 contents of this process are the same as in step S123. The EMS 60 executes the process of step S164 after executing the process of step S163.

  In step S164, the EMS 60 determines that the power purchased from the system power source S in the residential storage battery system (in the present embodiment, the Nth residential storage battery system 2N) disposed on the most upstream side is the lowest discharge threshold a. It is determined whether or not: If the EMS 60 determines that the power purchased from the system power source S in the Nth residential storage battery system 2N is not less than the minimum discharge threshold a (No in step S164), the process of step S162 is executed again.

  The case where the power purchased from the system power source S in the Nth residential storage battery system 2N is not less than the minimum discharge threshold a is a case where at least one residential storage battery system 20 is discharging. In addition, even if power is discharged from all the storage battery systems 20 for residential use set to the discharge mode, the power consumption of each house H is not covered (when the power for the shortage is purchased from the system power supply S) ).

  In such a case, the EMS 60 performs the process of step S162 again, and if possible (if there is a residential storage battery system 20 set in the stop mode), all of those set in 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 power from the residential storage battery system 20.

  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 lower than the minimum discharge threshold a (Yes in step S164), the storage battery system operation process is performed. Exit. The case where the power purchased from the system power source S in the Nth residential storage battery system 2N is equal to or lower than the minimum discharge threshold a is a case where at least one residential storage battery system 20 is discharging. In addition, when the power consumed by each house H is covered by the power discharged from each storage battery system 20 set to the discharge mode (the power shortage is not purchased from the system power supply S) Or the case where all the storage battery systems 20 for residential use are not discharging.

  In step S162, when the EMS 60 determines that the residential storage battery system 20 with 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 EMS 60 increases the amount of power from all the residential storage battery systems 20 set in the discharge mode. I can't. Thus, when the residential storage battery system 20 with the lowest discharge priority is set to the discharge mode, the shortage of power is purchased from the system power source S, and the purchased power is sent to each house H. Supplied.

  Thus, by controlling the operation (discharge) of the residential storage battery system 20 in the same manner as the storage battery system operation process according to the first embodiment, a plurality of storage battery system operation processes according to the fifth embodiment are performed. It is possible to eliminate the uneven discharge amount (unbalance of the remaining amount of storage battery) in the residential storage battery system 20. Thus, by eliminating the bias generated in the discharge amount in the plurality of storage battery systems 20 for homes, it is possible to equalize the charges that can be obtained among the plurality of homes H (residents).

  Moreover, in the process of the storage battery system operation | movement which concerns on 5th embodiment, unlike the process of the storage battery system operation | movement which concerns on 1st embodiment, it is based on judgment (step S121) whether the shared storage battery system 30 is discharged. Instead, in the plurality of residential storage battery systems 20 based on the determination (step S161) whether the power purchased from the system power source S in the Nth residential storage battery system 2N is greater than the minimum discharge threshold a. Eliminating the bias in the amount of discharge. Thus, even if the shared storage battery system 30 is not provided, it is possible to equalize the charges that can be obtained among a plurality of houses H (residents).

  In addition, in the process of the storage battery system operation | movement which concerns on 5th embodiment, although the process of step S164 is performed, the said process is abbreviate | omitted similarly to step S124 in the process of the storage battery system operation | movement which concerns on 1st embodiment. It is also possible (see processing of storage battery system operation according to the second embodiment (another example of the first embodiment)).

  Hereinafter, in FIG. 13 and FIG. 14, in the power supply system 200 according to the second embodiment, the processing of the storage battery system operation according to the second embodiment by the EMS 60 when the equal mode is executed (hereinafter, “ The storage battery system operation process according to the sixth embodiment ”will be described.

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

  The EMS 60 executes the process of step S171 if Yes in step S161.

  In step S171, the EMS 60 determines whether or not the remaining battery level of each residential storage battery system 20 is greater than a predetermined dischargeable threshold value b. When the EMS 60 determines that the remaining battery level of each of the residential storage battery systems 20 is greater than the dischargeable threshold value b (Yes in step S171), the process of step S162 is executed. Moreover, EMS60 judges that the storage battery residual amount of each storage battery system 20 is not larger than the dischargeable threshold value b (The storage battery residual amount of at least 1 or more residential storage battery system 20 is below the dischargeable threshold value b). 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 storage battery for the residential storage battery system 20 to discharge. That is, in this embodiment, the case where the remaining battery level of each residential storage battery system 20 is larger than the dischargeable threshold value b indicates a case where all the residential storage battery systems 20 can be discharged if they are in the discharge mode. Yes. Moreover, the case where the storage battery residual amount of each residential storage battery system 20 is not larger than the dischargeable threshold value b (the storage battery residual amount of at least one residential storage battery system 20 is equal to or less than the dischargeable threshold value b) is at least The case where one or more residential storage battery systems 20 cannot discharge even in the discharge mode is shown.

  In step S172, the EMS 60 determines whether or not the remaining battery level of each of the residential storage battery systems 20 is equal to or less than the dischargeable threshold value b. If EMS60 judges that the storage battery remaining amount of each storage battery system 20 for homes is not below the dischargeable threshold value b (it is No at step S172), the process of step S173 will be performed. In addition, the case where the storage battery residual amount of each residential storage battery system 20 is not less than the dischargeable threshold value b indicates a case where discharge is possible if at least one residential storage battery system 20 is in the discharge mode.

  In step S173, the EMS 60 extracts only the residential storage battery system 20 whose remaining storage battery capacity is greater 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 storage battery capacity of each of the residential storage battery systems 20 extracted, and sets the discharge priority of each of the extracted residential storage battery systems 20 based on the acquired storage battery remaining capacity. To do. The EMS 60 executes the process of step S174 after executing the process of step S173.

  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 with 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 in which the discharge priority is set in step S173 and has the highest discharge priority among the residential storage battery systems 20 currently set in the stop mode. The storage battery system 20 is changed to the discharge mode. EMS60 performs the process of step S176, after performing the process of step S175.

  In step S176, the EMS 60 determines that the power purchased from the system power source S in the residential storage battery system (in the present embodiment, the Nth residential storage battery system 2N) disposed on the most upstream side is the lowest discharge threshold a. It is determined whether or not: 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 less than the minimum discharge threshold a (No in step S176), the process of step S174 is executed again.

  Note that the case where the power purchased from the system power source S in the Nth residential storage battery system 2N is not less than the minimum discharge threshold a is at least the residential storage battery system 20 for 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. This is a case where it is not possible (when a shortage of power is purchased from the system power source S).

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

  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 lower than the minimum discharge threshold a (Yes in step S176), the process of step S177 is performed. Run. Note that the case where the power purchased from the system power source S in the Nth residential storage battery system 2N is equal to or lower than the minimum discharge threshold a is at least the residential storage battery system 20 for which the discharge priority is set in step S173. In the case where one or more residential storage battery systems 20 are discharging, and the power discharged from each residential storage battery system 20 set to the discharge mode, the power consumption of each house H can be covered. In this case, the case is shown (when the power for the shortage is not purchased from the system power source S) or the case where all the storage battery systems 20 for home are not discharged.

  Similarly, in the case of No in step S161, Yes in step S162, Yes in step S164, Yes in step S172, or Yes in step S174, EMS 60 performs step The process of S177 is executed.

  In addition, the case where it is No in step S161 is a case where the power consumption of each house H is covered (a case where insufficient power is not purchased from the system power source S) or all the storage battery systems 20 for houses. Shows a case where no discharge is performed. Moreover, the case where it is Yes in step S162 and the case where it is Yes in step S174 show the case where the storage battery system 20 for houses set to the stop mode does not exist. The case of Yes in step S164 means that the power consumption of each house H is covered (when the insufficient power is not purchased from the system power supply S) or all the storage battery systems 20 for houses. Shows a case where no discharge is performed. Moreover, the case where it is Yes in step S172 has shown the case where it cannot discharge even if all the storage battery systems 20 for houses are in discharge mode.

  Thus, if Yes in step S176, No in step S161, Yes in step S162, Yes in step S164, Yes in step S172, or Yes in step S174. The case where is the case where the process which increases the number of the storage battery systems 20 for houses set to discharge mode is not performed (it cannot perform or does not need to perform) is shown.

  Thus, in the process of the operation of the storage battery system according to the sixth embodiment, when the EMS 60 does not perform the process of increasing the number of residential storage battery systems 20 set in the discharge mode, the process of step S177 is executed. .

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

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

  In addition, when the storage battery residual amount of each residential storage battery system 20 set to the discharge mode is larger than the dischargeable threshold value b (Yes in step S178), all of the residential storage battery systems 20 that are in standby for discharge are used. 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 storage battery is on standby for discharging because of the surplus 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 to the discharge mode to the stop mode. Thus, the EMS 60 discharges not from the residential storage battery system 20 having a low discharge priority when there is a residential storage battery system 20 that is in a standby state for discharge due to surplus in the power consumption of each house H. Electric power is discharged from the high-priority residential storage battery system 20. The EMS 60 executes the process of step S181 after executing the process of step S179.

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

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

  In step S180, the EMS 60 extracts the residential storage battery system 20 whose remaining battery capacity is equal to or less than the dischargeable threshold value b from all the residential storage battery systems 20 set in the discharge mode, and extracts each of the extracted residential storage battery systems. 20 is changed to the stop mode. Thus, the EMS 60 sets the storage battery system 20 for residential use that does not remain to the extent that the remaining amount of storage battery can be discharged among the storage battery systems 20 for residential use set to the discharge mode to the stop mode. The EMS 60 executes the process of step S181 after executing the process of step S180.

  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 EMS 60 determines that all the residential storage battery systems 20 set to the discharge mode are not discharged (No in step S181), the process of step S178 is executed again.

  In addition, when all the storage battery systems 20 for houses set to discharge mode are not discharging (it is No at step S181), it is standby for discharge among all the storage battery systems 20 for houses set to discharge mode. The case where the storage battery system 20 for houses is present, that is, the case where the power consumption of each house H is covered and the number of the storage battery systems 20 for housing more than necessary is set to the discharge mode is shown.

  In such a case, the EMS 60 performs the process of step S178 again, so that the residential storage battery system 20 with the lowest discharge priority is minimized so as not to discharge from the residential storage battery system 20 with the lowest discharge priority. Change to stop mode.

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

  In Step S177, when EMS 60 determines that there is no residential storage battery system 20 that is in standby for discharge among all the residential storage battery systems 20 set in the discharge mode (No in Step S177), the storage battery system operation is performed. The process ends. Of all the residential storage battery systems 20 set in the discharge mode, when there is no residential storage battery system 20 that is in standby for discharge, the number of residential storage battery systems 20 set in the discharge mode is further reduced. The case where it cannot be made is shown.

  Thus, in the process of the storage battery system operation | movement which concerns on 6th embodiment, while controlling the operation | movement (discharge and discharge stop) of the storage battery system 20 for houses, it differs from the process of the storage battery system operation | movement which concerns on 5th embodiment. In addition, it is not only the determination whether 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 (step S161), but also the remaining battery level of each residential storage battery system 20 is Based on the determination whether or not the dischargeable threshold value is larger than the dischargeable threshold value b (step S171), etc., the discharge amount deviation in the plurality of residential storage battery systems 20 (storage battery) while finely adjusting the discharge amount from the residential storage battery system 20 (Balance in remaining amount) can be solved. Thus, by eliminating the bias generated in the discharge amount in the plurality of storage battery systems 20 for homes, it is possible to more reliably achieve equalization of charges that can be obtained among the plurality of homes H (residents).

  In addition, in the process of the storage battery system operation | movement which concerns on 6th embodiment, although the process of step S164, step S176, and step S181 is performed, it is the same as that of step S124 in the process of the storage battery system operation | movement which concerns on 1st embodiment. Moreover, the said process can also be abbreviate | omitted (refer the process of the storage battery system operation | movement which concerns on 2nd embodiment (another example of 1st embodiment)).

As described above, in the power supply system 1 according to the present embodiment,
A plurality of residential solar power generation systems 40 (power generation systems) capable of generating power using natural energy;
It is provided corresponding to each of the plurality of residential solar power generation systems 40, can be charged with power from the corresponding residential solar power generation system 40, can be supplied to the house 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;
EMS 60 (control unit) for switching the operation mode of the residential storage battery system 20;
Comprising
The residential storage battery system 20 includes:
As the operation mode, it is possible to execute a discharge mode that enables discharge according to a request of the house H (load), or a stop mode that disables discharge,
The EMS 60 (control unit)
While acquiring the storage battery remaining amount of the residential storage battery system 20, the plurality of residential storage battery systems 20 are prioritized in the order of the acquired remaining storage battery amount,
The highest-priority residential storage battery system 20 in the priority order is set to the discharge mode, and the other residential storage battery systems 20 are set to the stop mode.

With such a configuration, it is possible to prevent the discharge and charge from being biased toward 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). In addition, in order to prevent the amount of discharge in the plurality of residential storage battery systems 20 from being biased, it is possible to equalize the lifetime (lifetime) in the plurality of residential storage battery systems 20. Moreover, it becomes easy to ensure an empty capacity | capacitance in the said storage battery system 20 for houses by performing discharge preferentially from the storage battery system 20 for houses with much residual storage battery. This makes it easy to charge the surplus power, and can suppress the surplus power from being wasted.

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 power from the house storage battery system 20 in the discharge mode is insufficient for the demand of the house H (load). )
The EMS 60 (control unit)
When electric 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 highest-priority residential storage battery system 20 in the priority order is set as the discharge mode.

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

In the power supply system 1 according to the present embodiment,
The plurality of residential storage battery systems 20 are connected to the house 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 and charging from being biased toward a specific residential storage battery system 20 among the plurality of residential storage battery systems 20.

In the power supply system 1 according to the present embodiment,
The plurality of residential storage battery systems 20 are owned by any of the residents (a plurality of consumers) of the house H,
The deficient power supply system is shared by residents (a plurality of consumers) of the house H.

  With such a configuration, using a shared system of residents of a plurality of houses H that supplies power to a load, the discharge and charging are biased toward a specific house storage battery system 20 among the plurality of house storage battery systems 20. It can prevent more effectively.

The residential solar power generation system 40 is an embodiment of the power generation system.
Moreover, the storage battery system 20 for houses is one Embodiment of a storage battery system.
Moreover, the shared storage battery system 30 is an embodiment of the insufficient power supply system.
Moreover, the house H is one embodiment of the load.
Moreover, EMS60 is one Embodiment of a control part.
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-described configuration, and various modifications can be made within the scope of the invention described in the claims.

  For example, in the above-described embodiment, the power retailer supplies the power purchased collectively from the power company or the power purchased from the plurality of houses H as appropriate between the plurality of houses H (accommodation). It does not have to be a one-time purchase from a power company.

  Moreover, although the residential solar power generation system 40 and the shared solar power generation system 50 are assumed to generate power using sunlight, they use other natural energy instead of the residential solar 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).

  Further, it is possible to select an appropriate control unit instead of the EMS 60 for switching the eco mode, the discharge mode, and the stop mode of the residential storage battery system 20.

  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 specific values (hours) of the set time A and the set time B. Is not limited and can be set arbitrarily. In addition, the set time A (set time B) is for determining whether or not the solar photovoltaic power generation system 40 is irradiated with sunlight, and is thus changed as appropriate according to the season (sunshine hours) and the like. May be.

  In addition, the EMS 60 determines whether or not the residential solar power generation system 40 is irradiated with sunlight by determining whether or not the current time is the set time A (set time B) in the time zone processing. However, the present invention is not limited to this, and it is also possible to determine whether or not sunlight is irradiated by detecting the power generation amount of the residential solar power generation system 40. It is also possible to separately provide an illuminometer and determine whether or not sunlight is irradiated.

  Moreover, in the said embodiment, one photovoltaic power generation system (residential photovoltaic power generation system 40 and shared photovoltaic power generation system 50) is provided for one storage battery system (residential storage battery system 20 and shared storage battery system 30). Although the provided (connected) configuration is shown, the present invention is not limited to this. For example, a configuration in which a plurality of photovoltaic power generation systems are connected to one storage battery system is also possible. It is also possible to adopt a configuration in which a plurality of storage battery systems are connected to one solar power generation system.

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

DESCRIPTION OF SYMBOLS 1 Electric 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 Housing S System power supply

Claims (4)

A plurality of power generation systems capable of generating power using natural energy;
A plurality of storage battery systems provided corresponding to the plurality of power generation systems, capable of charging power from the corresponding power generation systems, supplying power to a load, and capable of executing a plurality of operation modes related to operation When,
A controller that switches the operation mode of the storage battery system;
Comprising
The storage battery system includes:
As the operation mode, it is possible to execute a discharge mode that enables discharge according to a request of the load, or a stop mode that disables discharge,
The controller is
While acquiring the storage battery remaining amount of the storage battery system, prioritize the plurality of storage battery systems in the order of the acquired storage battery remaining amount,
The storage battery system at the top of the priority is set as the discharge mode, and the other storage battery systems are set as the stop mode.
Power supply system. Comprising an insufficient power supply system for supplying power to the load when the power from the storage battery system in the discharge mode is insufficient with respect to the demand of the load;
The controller is
When power is supplied from the insufficient power supply system to the load,
Among the storage battery systems in the stop mode, the storage battery system of the highest priority is set as the discharge mode.
The power supply system according to claim 1. The plurality of storage battery systems are connected to the load side more than the insufficient power supply system,
The power supply system according to claim 2. The plurality of storage battery systems are owned by any of a plurality of consumers,
The insufficient power supply system is shared by the plurality of consumers,
The power supply system according to claim 2 or claim 3.

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