JP2019118185A - Power supply system - Google Patents

Abstract

To provide a power supply system capable of suppressing occurrence of power purchase from a system power source by dealing with a sudden change in power consumption of a load.SOLUTION: When supplying power discharged from multiple power storage devices H50 and M50 to a load H40 in a daytime zone, in a case where the daytime zone is started, an EMS 70 performs a discharge instruction or a standby instruction to the multiple power storage devices H50 and M50 according to discharge priorities set to the multiple power storage devices H50 and M50. In a case where there is one non-discharged power storage device in the multiple power storage devices H50 and M50, there is no dischargeable residual power in the one power storage device and the one power storage device is the most upstream power storage device M50, the most upstream power storage device M50 is charged with generated power of a photovoltaic power generation part M60 and, even in a case where the discharge instruction is not performed, brought into a dischargeable state.SELECTED DRAWING: Figure 4

Description

  The present invention relates to the technology of a power supply system that supplies power discharged from a plurality of power storage devices to a load.

  Conventionally, the technology of a power supply system for supplying power discharged from a plurality of power storage devices to a load is known. For example, it is as described in Patent Document 1.

  The power supply system described in Patent Document 1 includes a plurality of power storage systems connected in series between a system power supply and a load, and a control unit that controls the plurality of power storage systems. The control unit sets a predetermined discharge priority to discharge of the plurality of power storage systems, and controls discharge of the plurality of power storage systems in accordance with the set discharge priority. With such a configuration, in the power supply system, it is possible to suppress the deviation of the discharge amount in each power storage system.

JP, 2017-163711, A

  However, when the control unit controls all of the plurality of power storage systems according to the discharge priority order as in the power supply system described in Patent Document 1, for example, when performing a discharge instruction to all the power storage systems It takes time because of the control flow. Therefore, for example, when the power consumption of the load suddenly increases, the system power supply may generate power purchase because it can not cope with the rapid change of the power consumption of the load.

  The present invention has been made in view of the circumstances as described above, and the problem to be solved is to respond to a rapid change in the amount of power consumption of a load and to suppress the generation of electricity purchase from a system power supply. Power supply system capable of

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

  That is, according to claim 1, the plurality of power storage devices connected in series between the system power supply and the load, and the most upstream power storage device connected to the most system power side among the plurality of power storage devices are connected. And a control unit capable of controlling charge and discharge of the plurality of power storage devices, and generating a plurality of power generation units for distributing generated power between the system power supply and the load; The power supply system for supplying power discharged from the storage device to the load, wherein the control unit is configured to set the discharge priority for the plurality of storage devices when the predetermined period is started. Discharge instruction or standby instruction to the plurality of power storage devices based on the plurality of power storage devices, there is one power storage device that is not discharged, and the one power storage device has no dischargeable remaining amount And the one power storage device Wherein when a most upstream of the power storage device, the causes charge the generated electric power of the power generation unit at the most upstream of the power storage device, even if not performed discharge instruction is for a dischargeable state.

  According to a second aspect of the present invention, in the discharge priority order, when the predetermined period is started, the most upstream storage device is set to the top, and the most upstream storage device among the plurality of storage devices. The storage devices other than the above are set based on the integrated amount of discharged power which is the integrated amount of discharged power.

  According to a third aspect of the present invention, the control unit issues a discharge instruction to all of the plurality of power storage devices when the predetermined period is started.

  In claim 4, when the amount of purchased electricity from the system power supply is equal to or greater than a predetermined amount, the control unit instructs the storage device with the highest discharge priority among the storage devices for which a standby instruction has been issued, to discharge. It is something to do.

  According to a fifth aspect of the present invention, when the amount of purchased electricity from the system power source is smaller than the predetermined amount, the control unit instructs the storage device with the lowest discharge priority among the storage devices for which discharge instruction is performed. To do.

  In the sixth aspect, the control unit enables charging of the power generated by the power generation unit and the first mode in which the control unit operates based on the discharge instruction or the standby instruction, and flows between the system power supply and the load. A second mode capable of discharging power corresponding to the power to be stored can be set in each power storage device, and when the predetermined period is started, the first mode is set to the plurality of power storage devices If, after the start of the predetermined period, there is no dischargeable remaining amount in the one power storage device and the one power storage device is the most upstream power storage device, By switching the upstream power storage device from the first mode to the second mode, the most upstream power storage device is charged with the generated power of the power generation unit, and the discharge instruction is not issued. Be in a possible state

  The effects of the present invention are as follows.

  According to the first aspect of the present invention, it is possible to suppress the occurrence of purchase of electricity from the system power supply in response to a rapid change in the power consumption of the load.

  In the second aspect, the most upstream storage device can be used more effectively.

  According to the third aspect, it is possible to suppress the generation of the purchase from the system power supply.

  According to the fourth aspect, it is possible to increase the number of power storage devices in the dischargeable state while suppressing the deviation of the discharge amount in each power storage device.

  According to the fifth aspect, it is possible to reduce the number of power storage devices in the dischargeable state while suppressing the deviation of the discharge amount in each power storage device.

  According to the sixth aspect, the configuration can be made relatively simple.

FIG. 1 is a block diagram showing a configuration of a power supply system according to an embodiment of the present invention. The block diagram which showed an example of the supply aspect of electric power. The flowchart which showed the process regarding charge among power purchase control processing. The flowchart which showed the process regarding electric power interchange among power purchase suppression processing.

  Hereinafter, a power supply system 1 according to an embodiment of the present invention will be described with reference to FIG.

  The power supply system 1 is applied to a residential area T having a plurality of detached houses (houses H) and various facilities. In the present embodiment, in the residential area T, three houses H (a first house H1, a second house H2, and a third house H3) are provided as a plurality of (detached) houses H. In addition, in the residential area T, a meeting place M for the residents to use, for example, is provided as various facilities. In the residential district T, a power retailer purchases power from the power company (system power source S) as a batch, and the purchased power is appropriately supplied (sold) to each home H or meeting place M.

  The electric power supply system 1 supplies electric power purchased collectively by the electric power retailer from the electric power company among the multiple houses H (the first house H1, the second house H2 and the third house H3) or the meeting place M as appropriate ) Is a system to In the present embodiment, the power supply system 1 includes the distribution board 10, a plurality of houses H (power demand unit H20 and power supply unit H30), a meeting place M (power demand unit M20 and power supply unit M30), and EMS 70. Equipped with

  The distribution board 10 distributes the power supplied from the power supply source to a plurality of houses H and a meeting place M. The distribution board 10 is connected to the system power supply S via the distribution line La. In the present embodiment, as described later, a system power supply S, a power supply unit H30 of each house H described later, and a power supply unit M30 of the meetinghouse M are provided as a power supply source.

  The plurality of homes H (first home H1, second home H2 and third home H3) are configured to be able to supply (accommodate) power while the residents live to generate power demand. Specifically, the house H includes a power demand unit H20 as generating power demand and a power supply unit H30 as supplying power. Power demand unit H20 includes load H40 and power storage device H50. Further, the power supply unit H30 includes a solar power generation unit H60 and a power storage device H50.

  Thus, power storage device H50 is included in both power demand unit H20 and power supply unit H30.

  The load H40 is an appropriate electrical product provided in the house H. The load H40 consumes electricity.

  The storage device H50 charges and discharges the power from the system power source S and the power from the solar power generation unit H60 (generated power) as appropriate. Power storage device H50 includes a chargeable / dischargeable storage battery, a control unit that controls the operation of the storage battery, and the like. In addition, power storage device H50 does not discharge even in the dischargeable state when the remaining power becomes a predetermined value (30% or less in this embodiment) with respect to the capacity in preparation for a power failure. Is set as

  Power storage device H50 has a plurality of modes (modes) with respect to charge and discharge of electric power. The plurality of modes include a first mode (general mode) and a second mode (eco mode). The first mode and the second mode are set (switched) by the EMS 70 described later.

  When the first mode is executed, power storage device H50 is in a state capable of executing an operation instructed from EMS 70 described later. Specifically, when a discharge instruction is performed, power storage device H50 is in a dischargeable state, and is in a discharge state or a standby state according to the demand for power such as power demand unit H20 (load H40). When a standby instruction is issued, power storage device H50 is in a standby state in which charging and discharging are not performed. When a charge instruction is performed, power storage device H50 is in a chargeable state, and is in a charge state or in a standby state according to the charge amount of itself and the surplus power amount of solar power generation unit H60.

  When the second mode is executed, when the solar power generation unit H60 generates power, the power storage device H50 surplus power (power demand unit H20 (load H40), etc.) among the power generated by the solar power generation unit H60. Charge the surplus power for the demand for electricity, which may be simply referred to as "surplus power" below. Power storage device H50 discharges the charged power when the power generated by solar power generation unit H60 alone is insufficient for the power demand of power demand unit H20 and the like. Further, when there is surplus power in the solar power generation unit 60 and the power storage device H50 is fully charged, the surplus power flows backward to the system power supply S.

  When the first mode or the second mode is executed, power storage device H50 performs a load following operation when discharging. When the load following operation is performed, power storage device H 50 discharges the adjusted amount of electric power according to the detection result of a predetermined sensor (not shown). Note that the predetermined sensor is a connection portion of the storage device H50 (power supply unit H30) with the distribution board 10 (more specifically, a distribution line connecting the power supply unit H30 and the distribution board 10, The connection portion with the electronic board 10 is configured to be able to detect the power flowing toward the power demand unit H20. As described above, when the load following operation is performed, the power storage device H50 can discharge the power corresponding to the power flowing between the system power supply S and the load H40.

  The solar power generation unit H60 is a device that generates electric power using sunlight. The solar power generation unit H60 is configured of a solar cell panel or the like. The solar power generation unit H60 is connected to a power storage device H50 similarly provided in the same house H. The solar power generation unit H60 is installed in a sunny place such as, for example, on the roof of the house H. The power generated by the solar power generation unit H60 can be charged to the corresponding power storage device H50 (provided similarly in the same house H).

  Each house H is connected to the distribution board 10 via a predetermined distribution line. In each house H, the power demand unit H20 and the power supply unit H30 are connected to the distribution board 10 via different distribution lines.

  The power demand part H20 of the first house H1, the second house H2 and the third house H3 is connected to the distribution board 10 via the distribution line Lb. The upstream side (distribution board side) end of the distribution line Lb is connected to the distribution board 10, and the downstream side (housing side) end is branched to form a first house H1, a second house H2, and a third The power demand section H20 of the house H3 is connected to each other. Thus, the power demand part H20 of the first house H1, the second house H2 and the third house H3 is connected to the distribution board 10 (and consequently the system power supply S) via the same (one) distribution line .

  On the other hand, the power supply units H30 of the first house H1, the second house H2 and the third house H3 are connected to the distribution board 10 via different distribution lines. Specifically, the power supply unit H30 of the first house H1 is connected to the distribution board 10 via the distribution line Lc1. The power supply unit H30 of the second house H2 is connected to the distribution board 10 via the distribution line Lc2. The power supply unit H30 of the third house H3 is connected to the distribution board 10 via the distribution line Lc3.

  Distribution line Lc1 is connected to the most upstream side (system power supply side) in distribution board 10 among distribution lines Lc1 and the like (distribution line Lc1, distribution line Lc2 and distribution line Lc3). Distribution line Lc3 is connected to the most downstream side in distribution board 10 among distribution lines Lc1 and the like. The distribution line Lc2 is connected between the distribution line Lc1 and the distribution line Lc3 in the distribution board 10.

  The meeting place M is configured to be able to supply power (flexibility) as power demand occurs due to the use of the residents and the like. Specifically, the meeting place M includes a power demand unit M20 as a power demand occurs, and a power supply unit M30 as a power supply unit. The power demand unit M20 includes a load M40 and a power storage device M50. Further, the power supply unit M30 includes a solar power generation unit M60 and a power storage device M50.

  Thus, power storage device M50 is included in both power demand unit M20 and power supply unit M30.

  The load M40 is an appropriate electrical product provided in the meetinghouse M. The load M40 consumes electricity.

  The power storage device M50 charges and discharges the power from the system power source S and the power (generated power) from the solar power generation unit M60 as appropriate. Power storage device M50 includes a chargeable / dischargeable storage battery, a control unit that controls the operation of the storage battery, and the like. In the case of a power failure, storage device M50 does not discharge even in the dischargeable state when the remaining power becomes a predetermined value (30% or less in the present embodiment) with respect to the capacity. Is set as

  Power storage device M <b> 50 of meeting house M has a first mode and a second mode with respect to charge and discharge of electric power, similarly to power storage device H <b> 50 of house H.

  The solar power generation unit M60 is a device that generates electric power using sunlight. The solar power generation unit M60 is configured of a solar cell panel or the like. The solar power generation unit M60 is connected to a power storage device M50 similarly provided in the meeting place M. The solar power generation unit M60 is installed, for example, in a sunny place such as on the roof of the meetinghouse M. The power generated by the solar power generation unit M60 can be charged to the power storage device M50.

  Meeting place M is connected to distribution board 10 via a predetermined distribution line. More specifically, in meeting place M, power demand unit M20 is connected to distribution board 10 via distribution line Ld. Further, the power supply unit M30 is connected to the midway portion of the distribution line Ld. The distribution line Ld is connected to the most upstream side (uppermost stream) in the distribution board 10 with respect to all the distribution lines connecting the power supply unit H30 of each house H and the distribution board 10.

  Thus, the power supply unit M30 of the meetinghouse M, the power supply unit H30 of the first house H1, and the power supply of the second house H2 to the distribution board 10 (between the system power supply S and the load H40 of each house H). The power supply units H30 of the unit H30 and the third house H3 are connected in series in order from the upstream side to the downstream side.

  The EMS 70 is an energy management system that manages the operation of the power supply system 1. The EMS 70 includes a storage unit such as a RAM and a ROM, an arithmetic processing unit such as a CPU, and an input / output unit such as an I / O. The EMS 70 can perform predetermined arithmetic processing, storage processing, and the like. In the EMS 70, various information, programs, and the like used when controlling the operation of the power supply system 1 are stored in advance.

  Specifically, the EMS 70 is electrically connected to the storage device H50 of each house H and the storage device M50 of the meetinghouse M (whether wired or wireless). The EMS 70 acquires various information such as the operation status (for example, the set mode, whether or not it is discharged, etc.) of the power storage device H50 and the power storage device M50, the remaining power, the discharged power, the chargeable amount, etc. be able to. In addition, the EMS 70 can acquire various information such as the operation status of the solar power generation unit H60 and the solar power generation unit M60, and the amount of generated power via the power storage device H50 and the power storage device M50. The EMS 70 may obtain the information directly from the solar power generation unit H60 and the solar power generation unit M60 instead of via the power storage device H50 and the power storage device M50.

  Further, the EMS 70 determines the mode of the storage device H 50 of each house H and the storage device M 50 of the meetinghouse M based on the acquired information etc., and causes the storage device H 50 and the storage device M 50 to execute the determined mode. be able to.

  In addition, when causing the power storage device H50 and the power storage device M50 to execute the first mode, the EMS 70 can perform a discharge instruction, a charge instruction, and a standby instruction based on the acquired information or the like.

  Further, the EMS 70 can determine a discharge priority to be described later with respect to the power storage device H50 and the power storage device M50 based on the acquired information or the like. The discharge priority is mainly used when the first mode is performed, and is a discharge priority among all power storage devices.

  Further, in setting of the discharge priority, among all the power storage devices (power storage device H50 and power storage device M50), connected most upstream in distribution board 10 (between system power supply S and load H40 of each house H) The stored power storage device is determined as the one with the highest priority of discharge (first). That is, in the present embodiment, the power storage device M50 of the meeting place M is determined to be the first (highest) discharge priority.

  Further, the second and lower discharge priorities are determined based on the integrated discharge power amount of remaining power storage devices H50 other than power storage device M50 among all power storage devices. Specifically, among all power storage devices H50, the smaller the integrated discharge power amount, the higher the priority is determined. The integrated discharge power amount is a total integrated value of a predetermined period (in the present embodiment, from the time when each power storage device H 50 is installed to 23:00 of the previous day). The predetermined period is not limited to this, and can be any period.

  Below, an example of the supply aspect of the electric power in the electric power supply system 1 is demonstrated using FIG.

  In addition, below, the electrical storage apparatus H50 of each house H assumes that 1st mode is set. Also, in the first mode, power storage device H50 of each house H is in the late-night power time zone (in this embodiment, from 23:00 to 6:59 of the next day) where the electricity rates are relatively inexpensive, It is assumed that a charge instruction has been made. In addition, it is assumed that the storage device H50 of each house H is instructed to discharge during the daytime time zone (in this embodiment, from 7:00 to 22:59) in which the electricity price is relatively expensive. Do.

  In addition, in order to prevent the power storage device M50 of the meetinghouse M from performing load following operation and discharging in the late-night power period, the late-night power period is put in a standby state, and the second mode is started from the daytime period. Is assumed to be set.

  As described above, the power storage device H50 of each house H is not charged with the power generated by the solar power generation unit H60, and is charged with relatively inexpensive midnight power. In addition, the power storage device M50 of the meetinghouse M is not charged with late-night power, and the generated power of the solar power generation unit M60 is charged.

  In the power supply system 1 according to the present embodiment, the power discharged from the plurality of power storage devices (the power storage device H50 and the power storage device M50) may be supplied to the load H40 of each house H in the daytime time zone. it can. Therefore, in the following description, it is assumed that the current time is a daytime time zone. In the following, the daytime time zone (between 7 o'clock and 22:59) may be referred to as a "power interchange time".

  In the power demand part H20 of each house H, when the demand for power occurs (for example, when the load H40 consumes power), the power from the power supply source passes the distribution line Lb from the distribution board 10 It is supplied to the load H40 of each house H via the same. In the present embodiment, a system power supply S, a power supply unit H30 of each house H, and a power supply unit M30 of the meetinghouse M are provided as a power supply source.

  In each house H, as shown in FIG. 2, the power generated by the solar power generation unit H60 of the power supply unit H30 is distributed via predetermined distribution lines (distribution line Lc1, distribution line Lc2, and distribution line Lc3). It is distributed to the board 10. The generated power of the solar power generation unit H60 distributed to the distribution board 10 is supplied to the load H40 of each house H via the distribution line Lb. When the power generated by the solar power generation unit H60 is surplus with respect to the load H40, the surplus power is circulated in the distribution board 10 to the system power supply S side. When the power generated by the solar power generation unit H60 is insufficient for the load H40, the power from the system power supply S is distributed to the distribution board 10. The electric power from the system power source S distributed to the distribution board 10 is supplied to the load H40 of each house H via the distribution line Lb.

  Further, when the power from the system power source S flows through the distribution board 10, the power storage device H50 of each house H discharges according to the load following operation according to the power flowing through the distribution board 10. Thus, the power discharged from power storage device H50 of each house H is distributed to distribution board 10 via predetermined distribution lines (distribution line Lc1, distribution line Lc2, and distribution line Lc3). The power discharged from the storage device H50 of each house H distributed to the distribution board 10 is supplied to the load H40 of each house H via the distribution line Lb. Thus, when the power discharged from the power storage device H50 of each house H is supplied to the load H40, the power from the system power supply S decreases.

  Moreover, as shown in FIG. 2, when the solar power generation part M60 of the meeting place M is producing electric power, the electric power generated by the solar power generation part M60 is distributed to the distribution board 10 via the distribution line Ld. Be done. The generated power of the photovoltaic power generation unit M60 distributed to the distribution board 10 is supplied to the load H40 of each house H via the distribution line Lb. When the power generated by the photovoltaic power generation unit M60 is surplus with respect to the load H40, the surplus power is charged to the power storage device M50 of the meeting place M. Further, when the surplus power can not charge the storage device M 50 any more (for example, when the storage device M 50 is fully charged), the surplus power is distributed via the distribution line Ld to the distribution board 10. And the reverse power flow to the system power supply S.

  According to such a power supply mode, in the power supply system 1, the power from the power supply unit H30 (the solar power generation unit H60 and the storage device H50) of each house H is not limited to the load H40 of the house H itself. , The load H40 of another house H can also be supplied (bodied).

  According to such a power supply mode, it is possible to supply (accommodate) the load H40 of each house H with the power stored in the storage device H50, that is, relatively inexpensive late-night power.

  Further, in the present embodiment, when charging the power storage device H50 of each house H using the power from the system power source S, the residents of each house H purchase the power from the power retailer. Become. Thus, the residents of each house H can purchase and use power that is relatively cheaper than the general price. Further, the power generated by the solar power generation unit H60 of each house H and the power discharged from the power storage device H50 are purchased by the power retailer from the residents of each house H. Further, the surplus power (that is, the reversely flowed power), which is the power generated by the solar power generation unit H60 of each house H, is purchased by the power company from the power retailer.

  Here, in the distribution board 10 (between the system power supply S and the load H40 of each house H), as described above, the power supply unit M30 of the meetinghouse M, the power supply unit H30 of the first house H1, the second The power supply unit H30 of the house H2 and the power supply unit H30 of the third house H3 are connected in series in order from the upstream side to the downstream side.

  Therefore, when all the power storage devices discharge in the load following operation, the power storage device H50 of the third house H3 connected most downstream is most easily discharged. Further, the power storage device H50 of the second home H2 connected to the upstream side of the power storage device H50 of the third home H3 is configured to be easy to discharge next. Further, the power storage device H50 of the first home H1 connected to the upstream side of the power storage device H50 of the second home H2 is configured to be easy to discharge next. In addition, the storage device M50 of the meeting place M connected to the upstream side of the storage device H50 of the first house H1 is configured to be the next most likely to discharge (that is, the least likely to discharge).

  In addition, when the dischargeability (hardness) of each power storage device is different from each other, the discharge amount in each power storage device tends to be biased. As described above, if the discharge amounts in the respective power storage devices are unevenly distributed, the degree of deterioration in the respective power storage devices may be different, and the power sales amount to the power retailer may be different, which is not desirable. Therefore, in order to prevent the occurrence of such a bias, it is assumed that the power storage device H50 or the power storage device M50 is controlled in accordance with the above-described discharge priority.

  However, when the storage device H50 or the storage device M50 is controlled according to the discharge priority order, for example, it takes time in relation to the control flow to issue a discharge instruction to all the storage devices, so the load H40 In the case where the power consumption of the power supply suddenly increases, it may not be possible to cope with the rapid change of the power consumption of the load H40. In such a case, unintended (essentially unnecessary) power purchase may occur from the system power supply S.

  Therefore, in the power supply system 1, a specific process (hereinafter, referred to as "power purchase suppression process") can be executed so as to be able to cope with a rapid change in the power consumption of the load H40. The following describes the power purchase suppression process.

  As described above, the power purchase suppression process is a process for responding to a sudden change in the amount of power consumption of the load H40 and suppressing occurrence of unintended power purchase. The power purchase suppression process is a process executed by the EMS 70, and is performed in a one-minute cycle in the present embodiment. The purchase suppression process includes a process related to charging and a process related to power interchange.

  Below, the process regarding the charge performed by EMS70 is demonstrated using the flowchart of FIG.

  The processing relating to charging is mainly processing for charging of each power storage device outside the power interchange time. In addition, when the process regarding charge is started, 1st mode is performed in all the electrical storage apparatuses (The electrical storage apparatus M50 of the meeting place M and the electrical storage apparatus H50 of each house H).

  In step S10, the EMS 70 determines whether or not the current time is within the power interchange time (in this embodiment, from 7 o'clock to 22:59). If the EMS 70 determines that the current time is within the power interchange time (step S10: YES), the EMS 70 ends the process related to charging, and then executes the process related to power interchange (see FIG. 4). On the other hand, when the EMS 70 determines that the current time is not within the power accommodation time (step S10: NO), the process proceeds to step S11.

  In step S11, the EMS 70 determines whether the current time is the end time of the power accommodation time (23 o'clock in the present embodiment). If the EMS 70 determines that the current time is not the end time of the power interchange time (step S11: NO), the process (charging suppression process) relating to charging is temporarily ended. On the other hand, if the EMS 70 determines that the current time is the end time of the power accommodation time (step S11: YES), the process proceeds to step S12.

  In step S12, the EMS 70 issues a standby instruction to all of the power storage devices (the power storage devices M50 of the meeting place M and the power storage devices H50 of each house H). Thus, all power storage devices are in a standby state in which charging and discharging are not performed. Next, the EMS 70 transfers the process to step S13.

  In step S13, the EMS 70 acquires the chargeable amount of each power storage device. In addition, when the power storage unit S charges the power (midnight power) for each power storage device based on the acquired chargeable amount, the EMS 70 requires a period (hereinafter, referred to as “full charge”). Calculate “charging period”. Next, the EMS 70 transfers the process to step S14.

  In step S14, the EMS 70 determines, based on the charging period calculated in step S13, a time zone in which charging is actually performed for each power storage device (hereinafter, referred to as "determined charging time zone"). Specifically, based on the charging period calculated in step S13, EMS 70 overlaps the determined charging time zone of each power storage device in the late-night power period (from 6 pm to 6 o'clock on the next day). The determined charging time zone of each power storage device is determined so that the peak caused by doing is minimized. In this way, by minimizing the peak, it is possible to prevent, for example, the amount of electricity purchased from the system power source S per unit time from exceeding the amount of contract with the electric power company, and hence the power of the breaker. It is possible to suppress the blocking.

  Thus, in step S14, when the EMS 70 determines the determined charging time zone of each power storage device, the EMS 70 issues a charging instruction to the power storage device whose current time has become the determined charging time zone. In all the power storage devices, the first mode is executed. Thus, each power storage device becomes chargeable in its determined charging time zone, and charges late-night power. Next, the EMS 70 transfers the process to step S15.

  In step S15, the EMS 70 determines the discharge priority of the daytime period after the current midnight power period (i.e., the period from 7 o'clock to 23 o'clock, that is, the period of time in which the discharge is performed on the day). After the process of step S15, the EMS 70 temporarily ends the process related to charging.

  Below, the process regarding the power interchange performed by EMS70 is demonstrated using the flowchart of FIG.

  The process relating to the power interchange is mainly the process of supplying (interleave) power to the load 40H of each storage device within the power interchange time.

  In step S21, the EMS 70 determines whether the current time is the start time of the power accommodation time (in the present embodiment, seven o'clock). If the EMS 70 determines that the current time is the start time of the power accommodation time (step S21: YES), the process proceeds to step S22. On the other hand, when the EMS 70 determines that the current time is not the start time of the power accommodation time (step S21: NO), the process proceeds to step S23.

  In step S21, the process proceeds to step S22 when the current time is 7 o'clock, while the process proceeds to step S23 when the current time is from 7:00 to 23:59. Will be migrated. That is, when the process related to power interchange is executed, in most cases, the process proceeds to step S23.

  In step S22, the EMS 70 issues a discharge instruction to all power storage devices. Thus, all power storage devices are in the dischargeable state. Thus, at 7 o'clock, all the power storage devices are in the discharged state or in the standby state according to the amount of power consumption of the load H40 of each house H. After the process of step S22, the EMS 70 temporarily ends the process related to power interchange (power purchase suppression process).

  In step S23, the EMS 70 determines whether there is a non-discharged power storage device among all the power storage devices. Here, the process of step S23 is shifted, as described above, when the current time is from 7:01 to 23:59. That is, the process of step S23 is shifted after the process of step S22 (shifted to 7 o'clock). Therefore, when the process proceeds to the process of step S23, all the power storage devices are in the dischargeable state.

  If the EMS 70 determines that there is a power storage device that has not been discharged (step S23: YES), the process proceeds to step S24. On the other hand, when the EMS 70 determines that there is no power storage device that has not been discharged (step S23: NO), the processing related to the power interchange is once ended.

  In step S24, the EMS 70 determines whether the non-discharged power storage device has a dischargeable remaining amount. Thus, the EMS 70 determines whether the reason why the power storage device is not discharged is because there is no dischargeable remaining amount. Specifically, the EMS 70 determines whether the remaining amount of the non-discharged power storage device is 30% or less of the capacity.

  If the EMS 70 determines that the non-discharged power storage device has no dischargeable remaining amount (the remaining amount is 30% or less of the capacity) (step S24: NO), the process proceeds to step S29. Migrate the process. In this case, the EMS 70 determines that the reason why the power storage device is not discharged is because there is no dischargeable remaining amount. On the other hand, if the EMS 70 determines that the non-discharged storage device has a dischargeable remaining amount (the remaining amount is more than 30% of the capacity) (step S24: YES), the step Transfer the process to S25. In this case, the EMS 70 determines that the reason why the power storage device is not discharged is not because there is no dischargeable remaining amount.

  In step S25, the EMS 70 determines whether or not the power purchase from the system power source S is equal to or more than a predetermined amount (for example, 500 W in the present embodiment). If the EMS 70 determines that the power purchase from the system power source S is 500 W or more (step S25: YES), the process proceeds to step S26. On the other hand, if the EMS 70 determines that the power purchase from the system power source S is smaller than 500 W (step S25: NO), the process proceeds to step S28.

  Note that the predetermined amount (500 W in the present embodiment) means whether the consumed power of the load H40 is covered by the power discharged from some of the power storage devices. It is a value set to determine. That is, the fixed amount is set to a value relatively close to 0 W, for example, with respect to the maximum discharge power amount of the power storage device. That is, when the power purchase from the system power source S is smaller than 500 W, it is assumed that the power consumed by the load H40 is covered by the power discharged from some of the power storage devices among all the power storage devices. Ru. In addition, when the power purchase from the system power supply S is 500 W or more, the power consumed by the load H40 is not covered by the power discharged from all the storage devices in the dischargeable state at this stage. is assumed.

  Since the power in the power supply system 1 tends to fluctuate constantly, such as the amount of power consumed by the load H40, in the present embodiment, it is determined whether the power purchase from the system power source S is a predetermined amount or more. The determination is changed according to the determination time. Specifically, the time zone in which the power fluctuation is large, such as the morning and evening time zones, is the EMS 70 when the power purchase from the system power supply S is twice or more continuously every one minute. And “Purchasing power from the system power source S is 500 W or more”. In addition, when the purchase from the system power supply S is equal to or more than a predetermined amount five times in a row every other minute, the EMS 70 indicates that “the purchase from the system power supply S is 500 W or more. It is determined that Thus, it is possible to prevent the control of each power storage device from becoming complicated due to power fluctuation.

  In step S26, the EMS 70 determines whether there is a power storage device to which a standby instruction has been issued. If the EMS 70 determines that there is a power storage device for which a standby instruction has been issued (step S26: YES), the process proceeds to step S27. On the other hand, if the EMS 70 determines that there is no power storage device for which a standby instruction has been issued (step S26: NO), the process related to power accommodation is once ended.

  In step S27, the EMS 70 issues a discharge instruction to the power storage device with the highest discharge priority among the power storage devices for which the standby instruction has been issued. That is, when the process of step S27 is performed, the EMS 70 determines that the number of power storage devices in the dischargeable state is insufficient. Thus, the storage device in the standby state is discharged according to the amount of power consumption of the load H40 of each house H. Thus, the number of power storage devices in the dischargeable state can be increased. After the process of step S27, the EMS 70 temporarily ends the process relating to the power interchange.

  Further, as described above, in step S28 in which it proceeds to the case where it is determined that the purchase of electricity from the system power source S is smaller than 500 W in step S25 (step S25: NO), the EMS 70 is instructed to discharge Among the storage devices, a standby instruction is issued to the storage device having the lowest discharge priority. That is, when performing the process of step S28, the EMS 70 determines that the number of storage devices in the dischargeable state is excessive. Thus, the power storage device in the dischargeable state is in the standby state regardless of the amount of power consumption of the load H40 of each house H. Thus, the number of power storage devices in the dischargeable state can be reduced. After the process of step S28, the EMS 70 temporarily ends the process related to the power interchange.

  In addition, as described above, when it is determined that the non-discharged storage device does not have a dischargeable remaining amount (the remaining amount is 30% or less of the capacity) in step S24 (step S24: NO) In step S29, the EMS 70 determines whether or not the power storage device having no remaining amount is the most upstream power storage device (in the present embodiment, the power storage device M50 of the meeting place M). Do. If the EMS 70 determines that the power storage device having no remaining amount is the most upstream power storage device (power storage device M50) (step S29: YES), the process proceeds to step S30. On the other hand, when the EMS 70 determines that the power storage device having no remaining amount is not the most upstream power storage device (power storage device M50) (step S29: NO), the process proceeds to step S25.

  In step S30, the EMS 70 determines whether the most upstream power storage device (power storage device M50) is in the second mode. If the EMS 70 determines that the most upstream power storage device (power storage device M50) is in the second mode (step S30: YES), the EMS 70 shifts the process to step S25. On the other hand, if the EMS 70 determines that the most upstream power storage device (power storage device M50) is not in the second mode (that is, the first mode) (step S30: NO), the process proceeds to step S31. Transition.

  In step S31, the EMS 70 changes the most upstream power storage device (power storage device M50) to the second mode. After the process of step S31, the EMS 70 shifts the process to step S32.

  In step S32, the EMS 70 changes the discharge priority of the most upstream storage device (power storage device M50), which has been changed to the second mode in step S31, from the highest to the lowest. After the process of step S32, the EMS 70 temporarily ends the process related to the power interchange.

  By executing such processing, when the remaining power of the power storage device M50 of the meeting place M on the most upstream side can be discharged once, the power storage device M50 charges the power generated by the solar power generation unit M60. , And can perform discharge following operation. Therefore, for example, when the power consumption amount of the load H40 suddenly increases, it is possible to discharge the power of the sudden increase from the power storage device M50, even if the other power storage device H50 is not immediately controlled. In this manner, in power supply system 1, not only the discharge amount deviation in each power storage device can be suppressed by controlling the plurality of power storage devices H50 and M50 based on the discharge priority, but also the power consumption of load H40. It is possible to cope with the sudden change of the power supply system, and in turn suppress the generation of the power purchase from the system power source S.

As described above, the power supply system 1 according to the embodiment of the present invention
A plurality of power storage devices H50 and M50 connected in series with each other between the system power supply S and the load H40,
Solar power generation that is connected to the most upstream power storage device M50 connected to the most system power source side among the plurality of power storage devices H50 and M50, and distribute generated power between the system power source S and the load H40 Part M60 (power generation part),
An EMS 70 (control unit) capable of controlling charge and discharge of the plurality of power storage devices H50 and M50;
Equipped with
A power supply system for supplying power discharged from the plurality of power storage devices H50 and M50 to the load H40 in a daytime time zone (within a predetermined period),
The EMS 70 (control unit)
When the daytime time zone (within a predetermined period) is started, a discharge instruction or a standby instruction is given to the plurality of power storage devices H50 / M50 based on the discharge priority order set for the plurality of power storage devices H50 / M50. Do,
Among the plurality of power storage devices H50 and M50, there is one power storage device that is not discharged,
In the case where there is no dischargeable remaining amount in the one power storage device and the one power storage device is the most upstream power storage device M50,
The power storage device M50 on the most upstream side is charged with the power generated by the solar power generation unit M60 (power generation unit), and can be discharged even when the discharge instruction is not performed.

  With such a configuration, it is possible to respond to a rapid change in the amount of power consumption of the load H40 and to suppress the occurrence of purchase of electricity from the system power supply S.

Also, in the power supply system 1,
The discharge priority is
When the daytime time zone (within a predetermined period) is started,
The most upstream storage device M50 is set to the top (first place),
Among the plurality of power storage devices H50 and M50, the power storage devices H50 other than the most upstream power storage device M50 are set based on a discharge power integrated amount which is an integrated amount of the discharged power.

  With such a configuration, immediately after the daytime time zone is started, the storage device M50 of the meeting place M on the most upstream side is urged to actively discharge, and priority is given to the other storage devices H50. The remaining power that can be discharged can be eliminated. Thus, when there is no remaining power that can be discharged, power storage device M50 can charge the generated power of solar power generation unit M60 (power generation unit) and perform discharge following operation and perform discharge. The power storage device M50 can be used more effectively.

Also, in the power supply system 1,
The EMS 70 (control unit)
When the daytime time zone (predetermined period) is started, a discharge instruction is issued to all of the plurality of power storage devices H50 and M50.

  With such a configuration, when the power consumption of the load H40 increases (peak occurs) at the beginning of the daytime time zone, the power discharged from all the power storage devices of the plurality of power storage devices H50 and M50 is Since it can be used, generation of purchase from the system power source S can be suppressed.

Also, in the power supply system 1,
The EMS 70 (control unit)
When the amount of electricity purchased from the system power source S is a certain amount or more,
Among the power storage devices for which a standby instruction has been issued, a discharge instruction is issued to the power storage device having the highest discharge priority.

  With such a configuration, when the number of storage devices in the dischargeable state is insufficient, the number of storage devices in the dischargeable state is increased while suppressing the deviation of the discharge amount in each storage device. be able to.

Also, in the power supply system 1,
The EMS 70 (control unit)
When the amount of electricity purchased from the system power source S is smaller than the above-mentioned fixed amount,
Among the power storage devices for which a discharge instruction has been issued, a standby instruction is given to the power storage device having the lowest discharge priority.

  With such a configuration, when the number of power storage devices in the dischargeable state is excessive, the number of power storage devices in the dischargeable state is reduced while suppressing deviation of the discharge amount in each power storage device. It can be done.

Also, in the power supply system 1,
The EMS 70 (control unit)
A first mode in which operation is performed based on a discharge instruction or a standby instruction;
A second mode for enabling charging of the power generated by the solar power generation unit (power generation unit) and for discharging the power corresponding to the power flowing between the system power source S and the load H 40 Settable to the device,
When the daytime time zone (predetermined period) is started, the first mode is set to all of the plurality of power storage devices H50 and M50,
After the start of the daytime period (predetermined period),
In the case where there is no dischargeable remaining amount in the one power storage device and the one power storage device is the most upstream power storage device M50,
By switching the most upstream power storage device M50 from the first mode to the second mode, the most upstream power storage device is charged with the generated power of the power generation unit and a discharge instruction is not issued. However, it is possible to discharge the battery.

  With such a configuration, by switching between two modes (a first mode and a second mode) possessed by the power storage device, the power purchase suppressing process (the process related to charging and the process related to power interchange) as described above is performed. It can be done. Thus, in the power supply system 1, the processing load of the EMS 70 can be reduced, and a relatively simple configuration can be achieved.

  As mentioned above, although embodiment of this invention was described, this invention is not limited to the said structure, A various change is possible within the range of the invention described in the claim.

  For example, in the present embodiment, although the power retailer supplies (accommodates) the power purchased collectively from the power company among the multiple houses H as appropriate, the power retailer purchases the power collectively from the power company. It is not necessary.

  Further, although the power purchase suppression process is performed during the daytime time zone in the present embodiment, the present invention is not limited to this, and can be performed during an arbitrary time zone.

  Further, the EMS 70 may be configured by, for example, a home server (not shown), a control unit of the power storage device, or an HEMS or the like provided in a house (when the application target of the power supply system 1 is a house).

  In addition, although the power generation unit uses sunlight as natural energy, it may use hydraulic power, wind power, tidal power or the like, or may not use natural energy.

1 Power supply system 70 EMS
H40 Load H50 Power Storage Device M50 Power Storage Device M60 Solar Power Generation Unit S System Power Supply

Claims (6)

A plurality of power storage devices connected in series with each other between the system power supply and the load;
A power generation unit connected to the most upstream power storage device connected to the most system power source side among the plurality of power storage devices, and for distributing generated power between the system power source and the load;
A control unit capable of controlling charging and discharging of the plurality of power storage devices;
Equipped with
A power supply system for supplying power discharged from the plurality of power storage devices to the load within a predetermined period,
The control unit
When the predetermined period is started, a discharge instruction or a standby instruction is given to the plurality of power storage devices based on the discharge priority order set for the plurality of power storage devices,
Among the plurality of storage devices, there is a single storage device not discharged,
In the case where there is no dischargeable remaining amount in the one power storage device and the one power storage device is the most upstream power storage device,
The most upstream power storage device is charged with the power generated by the power generation unit, and can be discharged even when a discharge instruction is not issued.
Power supply system. The discharge priority is
When the predetermined period starts,
The most upstream storage device is set to the top,
Among the plurality of power storage devices, a power storage device other than the most upstream power storage device is set based on a discharge power integrated amount which is an integrated amount of the discharged power.
The power supply system according to claim 1. The control unit
When the predetermined period starts, a discharge instruction is issued to all of the plurality of power storage devices,
The power supply system according to claim 1 or 2. The control unit
When the amount of electricity purchased from the system power supply is a certain amount or more,
Among the storage devices for which a standby instruction has been issued, a discharge instruction is given to the storage device having the highest discharge priority,
The power supply system according to any one of claims 1 to 3. The control unit
When the amount of electricity purchased from the system power supply is smaller than the above-mentioned fixed amount,
Among the storage devices for which a discharge instruction has been issued, a standby instruction is given to the storage device having the lowest discharge priority,
The power supply system according to claim 4. The control unit
A first mode in which operation is performed based on a discharge instruction or a standby instruction;
A second mode capable of charging the power generated by the power generation unit and discharging the power corresponding to the power flowing between the system power supply and the load can be set in each power storage device.
When the predetermined period is started, the first mode is set to all of the plurality of power storage devices,
After the start of the predetermined period
In the case where there is no dischargeable remaining amount in the one power storage device and the one power storage device is the most upstream power storage device,
By switching the most upstream power storage device from the first mode to the second mode, the most upstream power storage device is charged with the power generated by the power generation unit, and a discharge instruction is not issued. Also in the dischargeable state,
The power supply system according to any one of claims 1 to 5.

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