JP7090488B2 - Power supply system - Google Patents

Description

The present invention relates to a technique of a power supply system including a plurality of storage batteries.

Conventionally, the technique of a power supply system including a plurality of storage batteries has been known. For example, as described in Patent Document 1.

The power supply system described in Patent Document 1 is provided with a plurality of power storage devices (storage batteries) so as to correspond to a plurality of houses (consumers) (one house owns one power storage device). Ru). The power supply system is configured to be able to supply (accommodate) power from a plurality of power storage devices to a plurality of houses regardless of the correspondence with the house. A plurality of houses can get a charge according to the amount of discharge of the power storage device owned by the house. The power supply system preferentially discharges a power storage device having a small integrated discharge amount to equalize the integrated discharge amount. As a result, the plurality of houses can obtain the charges for accommodating the electric power substantially evenly.

However, if the integrated discharge amount is equalized as in Patent Document 1, the electric power from the power storage device owned by one house is supplied only to the one house without being supplied (accommodated) to the other house. The integrated discharge amount of the power storage device may increase or decrease as compared with the case of assuming (used alone). This could lead to profits and losses in multiple homes and create an unfair situation.

In the following, the occurrence of an unfair situation will be specifically described with reference to FIG. FIG. 9 shows information on the amount of electric power when the integrated discharge amounts of the plurality of power storage devices (storage battery system 20 shown in FIG. 9) are equalized. The reference numeral H1 shown in FIG. 9 indicates a first house, and owns a first power storage device (first storage battery system 21 shown in FIG. 9). Further, the reference numeral H2 shown in FIG. 9 indicates a second house, and owns a second power storage device (second storage battery system 22 shown in FIG. 9). Further, the reference numeral H3 shown in FIG. 9 indicates a third house, and owns a third power storage device (third storage battery system 23 shown in FIG. 9).

In FIG. 9, the integrated power consumption (cumulative power consumption for one month) of the first house H1, the second house H2, and the third house H3 is 50 kWh, 100 kWh, and 150 kWh, respectively. On the other hand, in FIG. 9, the integrated discharge amounts (integrated discharge amount for one month) of the first storage battery system 21, the second storage battery system 22, and the third storage battery system 23 are controlled so as to be equal to each other. , Each is 100kWh.

In the third house H3 shown in FIG. 9, when it is assumed that it is used alone, it is considered that about 150 kWh of electric power is discharged from the third storage battery system 23 in order to cover its own integrated power consumption (150 kWh). Therefore, it is considered that the third storage battery system 23 was able to discharge more electric power when used alone rather than equalizing the integrated discharge amount. As described above, in the third house H3, the integrated discharge amount of the third storage battery system 23 owned by the third house H3 is reduced as compared with the case where the integrated discharge amount is equalized, and the integrated discharge amount is reduced. As a result, the charges obtained from electric power retailers are reduced (losses).

Further, in the first house H1 shown in FIG. 9, assuming that it is used alone, it is considered that about 50 kWh of electric power is discharged from the first storage battery system 21 in order to cover its own integrated power consumption (50 kWh). Be done. Therefore, it is considered that the first storage battery system 21 was able to discharge more electric power as compared with the case where it was used alone by making the integrated discharge amount uniform. In this way, in the first house H1, by equalizing the integrated discharge amount, the integrated discharge amount of the first storage battery system 21 owned by the first storage battery system 21 increases as compared with the case where it is used alone, and the integrated discharge amount increases. As a result, the fees that can be obtained from electric power retailers will increase (profit).

In this way, if the integrated discharge amount is equalized, the integrated discharge amount of the plurality of storage battery systems 20 increases or decreases as compared with the case where it is assumed to be used alone, and each house H suffers a loss or gain according to the increase or decrease. There was a possibility that an unfair situation would occur.

Japanese Unexamined Patent Publication No. 2017-221050

The present invention has been made in view of the above situations, and the problem to be solved thereof is to provide a power supply system capable of suppressing the occurrence of an unfair situation.

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

That is, in claim 1, it is provided so as to correspond to a plurality of consumers having a load, and the discharged electric power can be supplied to the load of the plurality of consumers regardless of the correspondence relationship with the consumer. A plurality of storage batteries and a control unit that controls the discharge of the plurality of storage batteries based on the priority order regarding the discharge of the plurality of storage batteries are provided, and the control unit includes the integrated discharge amount of the plurality of storage batteries and the said. When the priority is set based on the power consumption of a plurality of consumers and it is assumed that only the storage battery corresponding to the consumer is discharged with respect to the load of the consumer, the storage battery is discharged. The estimated integrated discharge amount is calculated based on the power consumption amount, the priority is set based on the difference between the integrated discharge amount and the estimated integrated discharge amount, and the integrated discharge amount and the said The discharge priority is set so that the one having a small difference from the estimated integrated discharge amount is higher, and the storage battery having the higher discharge priority is preferentially discharged .

In claim 2 , the control unit calculates the estimated integrated discharge amount based on the specification information of the storage battery and the power consumption amount.

In claim 3 , a plurality of power generation units provided so as to correspond to the plurality of consumers and capable of generating power by using natural energy are further provided, and the control unit is the power consumption amount and the storage battery. The estimated integrated discharge amount is calculated based on the specification information and the power generation amount of the power generation unit.

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

In claim 1, it is possible to suppress the occurrence of an unfair situation. Further, in claim 1, the priority can be optimized.

In claim 2 , the estimated integrated discharge amount can be calculated accurately in consideration of the specification information of the storage battery.

In claim 3 , when the power generation unit is provided, the estimated integrated discharge amount can be calculated accurately in consideration of the integrated power generation amount of the power generation unit.

A block diagram showing a power supply system. A flowchart showing the discharge priority setting process. (A) The figure which showed a part of the power consumption. (B) Similarly, a diagram showing a part of the amount of power generation. The figure which superposed the power consumption amount and the power generation amount shown in FIG. A block diagram showing information on the amount of electric power on the day (first day) when the storage battery system is installed. The block diagram which showed the information about the electric energy in the 2nd day. A block diagram showing information on electric energy on the third day. The block diagram which showed the information about the electric energy in the 4th day. The block diagram which showed the information about the electric energy when the integrated discharge amount is equalized.

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

The power supply system 1 is assumed to be applied to a residential block T (aggregate of houses H) composed of a plurality of detached houses (houses H). Specifically, in the residential block T, a first house H1, a second house H2, and a third house H3 are provided as a plurality of (detached) houses H. In the residential block T, the electric power retailer purchases electric power in bulk from the electric power company (system power source S), and the purchased electric power is appropriately supplied (sold) to each house H.

The electric power supply system 1 appropriately supplies (accommodates) electric power, etc. purchased in bulk from an electric power company by an electric power retailer among a plurality of houses H (first house H1, second house H2, and third house H3). System. The power supply system 1 mainly includes a sensor unit 10, a plurality of storage battery systems 20 (first storage battery system 21, second storage battery system 22 and third storage battery system 23), and a plurality of solar power generation systems 30 (first solar power generation system). It is equipped with 31, a second solar power generation system 32 and a third solar power generation system 33) and an EMS 40.

The plurality of houses H (first house H1, second house H2, and third house H3) are buildings in which people live. An appropriate electric product is provided in each house H, and electric power is consumed.

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

The sensor unit 10 detects the electric power flowing through the distribution line L. The sensor unit 10 includes a first sensor 11, a second sensor 12, and a third sensor 13.

The first sensor 11, the second sensor 12, and the third sensor 13 each detect the electric power flowing through the arrangement location. The first sensor 11, the second sensor 12, and the third sensor 13 are configured to be capable of outputting signals related to the detection results, respectively. The first sensor 11, the second sensor 12, and the third sensor 13 are each provided so as to correspond to a predetermined storage battery system, and are electrically connected to the corresponding storage battery system.

Specifically, the first sensor 11 is electrically connected to the first storage battery system 21 described later. Further, the second sensor 12 is electrically connected to the second storage battery system 22 described later. Further, the third sensor 13 is electrically connected to the third storage battery system 23, which will be described later.

Further, the first sensor 11, the second sensor 12, and the third sensor 13 are arranged on the distribution line L immediately upstream of the connection point to which the corresponding storage battery system is connected. Specifically, the first sensor 11, the second sensor 12, and the third sensor 13 are located on the distribution line L immediately upstream of the first connection point P1, the second connection point P2, and the third connection point P3, which will be described later, respectively. Is placed in.

The plurality of storage battery systems 20 (first storage battery system 21, second storage battery system 22 and third storage battery system 23) are the plurality of solar power generation systems 30 (more specifically, among the plurality of solar power generation systems 30) described later. , A system for appropriately charging the electric power from the corresponding solar power generation system 30) and appropriately discharging the electric power. Each storage battery system 20 includes a storage battery that can be charged and discharged, a power conditioner that controls charging and discharging of the storage battery, and the like. Each storage battery system 20 is provided so as to correspond to a predetermined house H (one storage battery system 20 is provided for one house H). Each storage battery system 20 is owned by the predetermined house H (resident of the house H).

Specifically, the first storage battery system 21 is provided in the first house H1 and is owned by the resident of the first house H1. Further, the second storage battery system 22 is provided in the second house H2 and is owned by the resident of the second house H2. Further, the third storage battery system 23 is provided in the third house H3 and is owned by the resident of the third house H3.

Further, each storage battery system 20 is connected to the middle part of the distribution line L. Specifically, the first storage battery system 21, the second storage battery system 22, and the third storage battery system 23 are connected to the first connection point P1, the second connection point P2, and the third connection point P3 of the distribution line L, respectively. .. The first connection point P1, the second connection point P2, and the third connection point P3 are arranged in order from the downstream side (the plurality of residential sides) to the upstream side (system power supply S side) in the distribution line L. ing.

Further, each storage battery system 20 is charged with the power generated by a plurality of photovoltaic power generation systems 30 described later (more specifically, the corresponding photovoltaic power generation system 30 among the plurality of photovoltaic power generation systems 30). It is configured as follows. By charging each storage battery system 20 with the electric power generated by the solar power generation system 30 (particularly, surplus electric power) and discharging the charged electric power as necessary, the purchase amount of electric power from the grid power source S can be obtained. It can be reduced and promote self-sufficiency of electricity in the residential area T.

Further, as described above, each storage battery system 20 is electrically connected to the sensors (first sensor 11, second sensor 12 and third sensor 13) of the corresponding sensor unit 10. Each storage battery system 20 is configured so that a signal output from the sensor of the corresponding sensor unit 10 is input and the detection result of the sensor can be acquired based on the input signal. Each storage battery system 20 can perform a load follow-up operation for adjusting the amount of electric power to be discharged (output) based on the detection result of the sensor of the corresponding sensor unit 10.

The plurality of solar power generation systems 30 (first solar power generation system 31, second solar power generation system 32, and third solar power generation system 33) are systems for generating power using sunlight. The photovoltaic power generation system 30 includes a solar cell module formed by combining solar cells (cells) into a plate shape, a power conditioner for adjusting electric power from the solar cell module, and the like. Each solar power generation system 30 is provided so as to correspond to a predetermined house H (one solar power generation system 30 is provided for one house H). Each solar power generation system 30 is owned by the predetermined house H (resident of the house H).

Specifically, the first solar power generation system 31 is provided in the first house H1 and is owned by the resident of the first house H1. Further, the second solar power generation system 32 is provided in the second house H2 and is owned by the resident of the second house H2. Further, the third solar power generation system 33 is provided in the third house H3 and is owned by the resident of the third house H3.

Further, each photovoltaic power generation system 30 is connected to the storage battery system 20 of the owned house H. Specifically, the first photovoltaic system 31, the second photovoltaic system 32, and the third photovoltaic system 33 are the first storage battery system 21, the second storage battery system 22, and the third solar power generation system 33, respectively. Connected to. In this way, each storage battery system 20 and each solar power generation system 30 are provided so as to correspond to each other.

Each photovoltaic power generation system 30 is configured to be able to supply electric power to the distribution line L via each storage battery system 20. As a result, each house H (resident of house H) can appropriately use the electric power generated by each solar power generation system 30. Further, each photovoltaic power generation system 30 supplies the surplus power (surplus power) with respect to the power consumption of each house H out of the generated power to the storage battery system 20 of the house H, and the storage battery system. 20 can be charged. In the following, in the discharge from each storage battery system 20, the electric power from the storage battery and the solar power generation system 30 output to the distribution line L via each storage battery system 20 without being charged by the storage battery Power and shall be included. As described above, the amount of discharge from each storage battery system 20 in the present embodiment is the amount of electric power (output amount) output to the distribution line L.

The EMS 40 is an energy management system that manages the operation of the power supply system 1. The EMS 40 includes an arithmetic processing unit such as a CPU, a storage unit such as a RAM or ROM, an input / output unit such as a touch panel, and can perform predetermined arithmetic processing, storage processing, and the like. Various information, programs, and the like used when controlling the operation of the power supply system 1 are stored in the EMS 40 in advance.

Further, the EMS 40 is electrically connected to each storage battery system 20. The EMS 40 can output a predetermined signal to each storage battery system 20 and control the operation of each storage battery system 20. Further, the EMS 40 is configured so that a predetermined signal can be input from each storage battery system 20. As a result, the EMS 40 can acquire information regarding the operation of each storage battery system 20.

Further, the EMS 40 is electrically connected to each house H. The EMS 40 is configured so that a predetermined signal can be input from each house H. As a result, the EMS 40 can acquire information on the electric power of each house H.

Further, the EMS 40 can execute control for setting the discharge priority in each of the first storage battery system 21, the second storage battery system 22, and the third storage battery system 23. In the present embodiment, the discharge priority is the priority of discharge among the plurality of storage battery systems 20 (first storage battery system 21, second storage battery system 22 and third storage battery system 23).

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

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

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

The outline of the power supply (accommodation) mode by the power supply system 1 will be described below. In the following, it is assumed that the EMS 40 does not particularly set the discharge priority.

The electric power from the grid power source S is supplied to each house H via the distribution line L according to the power consumption of each house H. In this case, the first storage battery system 21 arranged on the most downstream side of the plurality of storage battery systems 20 first supplies the electric power generated by the first solar power generation system 31 to the distribution line L. Further, the first storage battery system 21 discharges the storage battery and supplies it to the distribution line L when the power consumption of each house H cannot be covered by the power generated by the first solar power generation system 31 alone. At this time, the first storage battery system 21 performs a load following operation based on the detection result of the first sensor 11 to discharge a predetermined amount of electric power. In this way, the electric power discharged from the first storage battery system 21 is supplied to each house H. When the electric power is discharged from the first storage battery system 21, the amount of electric power from the system power source S decreases.

Further, when the power consumption of each house H cannot be covered only by the power from the first storage battery system 21, the insufficient power is supplied to each house H from the system power source S. That is, the electric power from the grid power source S (the insufficient electric power) is supplied to each house H via the distribution line L. In this case, of the plurality of storage battery systems 20, the second storage battery system 22 arranged on the upstream side of the first storage battery system 21 first distributes the electric power generated by the second solar power generation system 32 to the distribution line L. Supply to. Further, the second storage battery system 22 discharges the storage battery and supplies it to the distribution line L when the power consumption of each house H cannot be covered by the power generated by the second solar power generation system 32 alone. At this time, the second storage battery system 22 performs a load following operation based on the detection result of the second sensor 12 to discharge a predetermined amount of electric power. In this way, the electric power discharged from the second storage battery system 22 is supplied to each house H. When the electric power is discharged from the second storage battery system 22, the amount of electric power from the system power source S is further reduced.

As described above, in the power supply system 1, when the power consumption of each house H cannot be covered, the discharge from the storage battery system 20 arranged one upstream side from the storage battery system 20 (where the discharge is started) is discharged. The operation of starting is repeated. In this way, with respect to the power consumption of each house H, discharge is sequentially started from the storage battery system 20 arranged on the downstream side to the storage battery system 20 arranged on the upstream side among the plurality of storage battery systems 20. .. Further, in each storage battery system 20, the electric power generated by each solar power generation system 30 is preferentially discharged with respect to the electric power charged in the storage battery.

If the power consumption of each house H cannot be covered even if the power is discharged from the third storage battery system 23, the insufficient power is purchased from the grid power supply S (power purchased from the grid power supply S). Is supplied to each house H).

In this way, in the power supply system 1, the electric power discharged from each storage battery system 20 is supplied not only to the resident (house H) who owns each storage battery system 20 but also to other residents (house H). Become. That is, the electric power discharged from each storage battery system 20 is appropriately exchanged between the plurality of houses H. In the present embodiment, each storage battery system 20 is fully charged in the midnight time zone, and power is exchanged between the plurality of houses H as described above in the daytime time zone.

Since the electric power discharged from each storage battery system 20 is once purchased by the electric power retailer, the charge corresponding to the electric power is paid to each house H (resident). Further, since the electric power supplied to each house H is purchased from the electric power retailer, each house H pays the electric power retailer a fee according to the power consumption.

Here, for example, when the discharge of each storage battery system 20 is controlled to equalize the integrated discharge amount, each storage battery system 20 (first storage battery system 21, second storage battery system 22 and third storage battery system 23) is used independently. Since the integrated discharge amount increases or decreases as compared with the case where it is assumed, an unfair situation may occur.

In the present embodiment, the single use means that only the electric power from the storage battery system 20 owned by the predetermined house H is supplied to the predetermined house H (the electric power is not exchanged with other houses H). Point to that. Specifically, the single use of the first storage battery system 21 means supplying only the electric power from the first storage battery system 21 owned by the first house H1 to the first house H1. Further, the single use of the second storage battery system 22 means supplying only the electric power from the second storage battery system 22 owned by the second house H2 to the second house H2. Further, the single use of the third storage battery system 23 means supplying only the electric power from the third storage battery system 23 owned by the third housing H3 to the third housing H3.

In the following, the occurrence of an unfair situation will be specifically described with reference to FIG.

FIG. 9 shows information on the amount of electric power when the integrated discharge amount of each storage battery system 20 is equalized. In FIG. 9, the integrated power consumption (cumulative power consumption for one month) of the first house H1, the second house H2, and the third house H3 is 50 kWh, 100 kWh, and 150 kWh, respectively. On the other hand, in FIG. 9, the integrated discharge amounts (integrated discharge amount for one month) of the first storage battery system 21, the second storage battery system 22, and the third storage battery system 23 are controlled so as to be equal to each other. , Each is 100kWh.

In the third house H3 shown in FIG. 9, assuming that it is used alone, in order to cover its own integrated power consumption (150kWh), it is assumed that about 150kWh of power is discharged from its own third storage battery system 23. Conceivable. Therefore, it is considered that the third storage battery system 23 was able to discharge more electric power when used alone rather than equalizing the integrated discharge amount. As described above, in the third house H3, the integrated discharge amount of the third storage battery system 23 owned by the third house H3 is reduced as compared with the case where the integrated discharge amount is equalized, and the integrated discharge amount is reduced. As a result, the charges obtained from electric power retailers are reduced (losses).

Further, in the first house H1 shown in FIG. 9, when it is assumed that it is used alone, about 50 kWh of electric power is discharged from the first storage battery system 21 owned by itself in order to cover its own integrated power consumption (50 kWh). It is considered to be. Therefore, it is considered that the first storage battery system 21 was able to discharge more electric power as compared with the case where it was used alone by making the integrated discharge amount uniform. In this way, in the first house H1, by equalizing the integrated discharge amount, the integrated discharge amount of the first storage battery system 21 owned by the first storage battery system 21 increases as compared with the case where it is used alone, and the integrated discharge amount increases. As a result, the fees that can be obtained from electric power retailers will increase (profit).

In this way, if the integrated discharge amount is equalized, the integrated discharge amount of each storage battery system 20 increases or decreases as compared with the case of using it alone, and each house H suffers a loss or gain according to the increase or decrease, which is an unfair situation. Could occur.

Therefore, the EMS 40 according to the present embodiment suppresses the occurrence of the unfair situation as described above by setting the discharge priority by the discharge priority setting process shown in FIG.

Hereinafter, the discharge priority setting process by the EMS 40 will be described. The discharge priority setting process is performed at a fixed timing (for example, at 24:00), and the discharge priority of the next day is set based on the information regarding the electric energy of the day (the day).

As shown in FIG. 2, first, in step S10, the EMS 40 acquires the integrated discharge amounts A1, A2, and A3 at the time of power interchange of the first storage battery system 21, the second storage battery system 22, and the third storage battery system 23, respectively. .. In the present embodiment, the integrated discharge amounts A1, A2, and A3 at the time of power interchange are when the first storage battery system 21, the second storage battery system 22, and the third storage battery system 23 are installed (hereinafter, "each storage battery system 20". It refers to the total amount of discharge from the first storage battery system 21, the second storage battery system 22, and the third storage battery system 23 to each house H from "at the time of installation") to the current day. In the present embodiment, the integrated discharge amounts A1, A2, and A3 at the time of power interchange include not only the power from the storage battery but also the first storage battery system 21, the second storage battery system 22, and the third storage battery without being charged by the storage battery. Power from the first photovoltaic power generation system 31, the second photovoltaic power generation system 32, and the third photovoltaic power generation system 33 discharged via the system 23 is also included. The EMS 40 acquires the integrated discharge amounts A1, A2, and A3 at the time of power interchange from, for example, the first storage battery system 21, the second storage battery system 22, and the third storage battery system 23. When the process of step S10 is completed, the EMS 40 shifts to step S20.

In step S20, the EMS 40 acquires the power consumption C1, C2, C3 of the first house H1, the second house H2, and the third house H3, and the power generation amounts D1, D2, and D3 of each photovoltaic power generation system 30, respectively. In the present embodiment, the power consumptions C1, C2, and C3 refer to the time elapsed from the time when each storage battery system 20 is installed to the day of each of the power consumed in the first house H1, the second house H2, and the third house H3. Refers to information that represents change. FIG. 3A shows data (a part of the power consumption C1, C2, C3) of the power consumption C1, C2, and C3 of the predetermined house H in a certain day. The EMS40 is currently used periodically (for example, at 1-minute intervals or 1-hour intervals) from, for example, the first house H1, the second house H2, and the third house H3 (more specifically, the power meter of each house H, etc.). The power consumption of C1, C2, and C3 is acquired by acquiring the power consumption of the above and appropriately totaling the acquired current power consumption.

Further, in the present embodiment, the power generation amounts D1, D2, and D3 are the storage batteries of the respective powers generated by the first solar power generation system 31, the second solar power generation system 32, and the third solar power generation system 33. Refers to information indicating changes over time from the time the system 20 is installed to the day of installation. FIG. 3B shows data (a part of the power generation amounts D1, D2, D3) of the power generation amounts D1, D2, and D3 of the predetermined house H in a certain day. The EMS 40 periodically (for example, at 1-minute intervals or 1-hour intervals) generates the current power generation amounts D1, D2, and D3 from the first storage battery system 21, the second storage battery system 22, and the third storage battery system 23. The power generation amounts D1, D2, and D3 are acquired by acquiring the electric power and appropriately totaling the acquired current generated electric power. As shown in FIG. 2, when the process of step S20 is completed, the EMS 40 shifts to step S30.

In step S30, the EMS 40 calculates the estimated integrated discharge amounts B1, B2, and B3 when the first storage battery system 21, the second storage battery system 22, and the third storage battery system 23 are used alone. In the present embodiment, the estimated integrated discharge amounts B1, B2, and B3 at the time of single use are the first storage battery system 21, the second storage battery system 22, and assuming that they are used independently from the time of installation of each storage battery system 20 to the day. It refers to each total discharge amount estimated to have been discharged from the third storage battery system 23.

In step S30, the EMS 40 includes the power consumption amounts C1, C2, C3 and the power generation amounts D1, D2, D3 acquired in step S20, and the storage batteries of the first storage battery system 21, the second storage battery system 22, and the third storage battery system 23. Based on the device specifications, the estimated integrated discharge amounts B1, B2, and B3 when used alone are calculated. In the present embodiment, the device specifications of the storage battery refer to the structure and design contents of the storage battery. The device specifications of the storage battery include the capacity of the storage battery, the maximum charge / discharge amount, the charge / discharge efficiency, the discharge depth, and the like. The EMS 40 acquires the device specifications of the storage battery from, for example, a storage unit.

The EMS 40 that has acquired the device specifications of the storage battery estimates, for example, how much power each storage battery system 20 outputs at a certain date and time, that is, the discharge power at the time of single use at a certain date and time, assuming that the EMS 40 is used alone. .. Then, the EMS 40 repeats the estimation while shifting the date and time (for example, at 1-minute intervals or 1-hour intervals), and accumulates the estimation results as appropriate to obtain the estimated integrated discharge amounts B1, B2, and B3 when used alone. calculate.

The procedure for estimating the discharge power when used alone at a certain date and time will be described below. In the following, when the power consumption of each house H is equal to or less than the power generated by each solar power generation system 30 at a certain date and time (hereinafter referred to as "first state"), the power consumption of each house H is each sun. A procedure for estimating is described separately for cases where the power generation is larger than the power generated by the optical power generation system 30 (hereinafter referred to as “second state”).

First, the procedure of estimation in the first state will be described. In the first state, since the power consumption is less than or equal to the generated power, the storage battery is not discharged. Further, in the first state, the generated power surplus with respect to the power consumption is charged in the storage battery or reversely flowed to the system power source S. If the surplus generated power is charged, that amount of power is not output to the distribution line L, so that the discharge power when used alone is reduced. On the other hand, when the surplus generated power is reverse-flowed, that amount of power is output to the distribution line L, so that the discharge power when used alone increases.

As described above, when each photovoltaic power generation system 30 is provided in each house H, it depends on the use of the surplus power generation power in the first state, that is, whether it is used for charging a storage battery or reverse power flow. , The discharge power when used alone fluctuates. Therefore, the EMS 40 determines the use of the surplus generated power by using the device specifications of the storage battery, and estimates the discharge power when used alone according to the determination result.

Specifically, for example, in a storage battery, the electric power that can be charged per unit time, that is, the maximum charge amount is fixed. Therefore, in the first state, the storage battery charges the surplus generated power within a range not exceeding the maximum charge amount. Therefore, the EMS 40 determines that, for example, when the difference between the generated power and the consumed power (the surplus generated power) is equal to or less than the maximum charge amount, the storage battery is charged with all the surplus generated power. In this case, since each storage battery system 20 discharges the same power as the power consumption, the EMS 40 estimates that the discharge power when used alone at a certain date and time is the same power as the power consumption. Thereby, the EMS 40 can estimate the discharge power at the time of single use in consideration of the decrease of the discharge power at the time of single use due to the charging of the surplus generated power.

On the other hand, the EMS 40 determines that when the difference between the generated power and the consumed power exceeds the maximum charge amount, the generated power consumes power and the surplus power is reversely flowed to the storage battery. In this case, each storage battery system 20 discharges electric power excluding the electric power (maximum charge amount) for charging the storage battery. Therefore, in this case, the EMS 40 estimates that the discharge power when used alone is the power obtained by subtracting the same power as the maximum charge amount from the generated power. Thereby, the EMS 40 can estimate the discharge power at the time of single use in consideration of the increase in the discharge power at the time of single use due to the reverse power flow of the surplus generated power.

Based on the above, the EMS 40 can determine the use of the surplus generated power (whether to charge or reverse power flow) using the maximum charge amount (device specifications of the storage battery). The discharge power when used alone can be estimated by taking into account the increase or decrease in the discharge power. Thereby, even if each solar power generation system 30 is provided in each house H, the discharge power at the time of single use can be estimated accurately. This makes it possible to accurately calculate the estimated integrated discharge amounts B1, B2, and B3 when used alone.

Next, the procedure of estimation in the second state in which the power consumption of each house H is larger than the power generated by each photovoltaic power generation system 30 will be described. In the second state, since the generated power alone cannot cover the power consumption, the storage battery is discharged. In this case, in addition to the generated power, the power discharged from the storage battery is also output to the distribution line L. Therefore, the EMS 40 estimates that the total power of the generated power and the power discharged from the storage battery (discharge power) is the discharge power when used alone. Further, the EMS 40 estimates the discharge power of the storage battery by using the device specifications of the storage battery.

Specifically, for example, in a storage battery, the electric power that can be discharged per unit time, that is, the maximum discharge amount is determined. Therefore, in the second state, the storage battery is discharged within a range not exceeding the maximum discharge amount. Therefore, the EMS 40 determines that, for example, when the difference between the power consumption and the generated power (power insufficient only by the generated power) is less than the maximum discharge amount, the storage battery discharges the same power as the difference. In this case, the EMS 40 estimates that the discharge power of the storage battery is the same power as the above difference. On the other hand, the EMS 40 determines that the storage battery discharges the same amount of power as the maximum discharge amount when the difference between the power consumption and the generated power exceeds the maximum discharge amount. In this case, the EMS 40 estimates that the discharge power of the storage battery is the same as the maximum discharge amount. According to this, the EMS 40 can accurately estimate the discharge power of the storage battery in consideration of the maximum discharge amount.

Further, for example, when the storage battery supplies a predetermined electric power (for example, an electric power of 500 W) to each house H, the storage battery does not discharge the same electric power as the predetermined electric power, but the predetermined electric power according to the discharge efficiency. A little more power (for example, 501 W power) than the power will be discharged. Therefore, the EMS 40 estimates the discharge power of the storage battery using the discharge efficiency in the second state. For example, when it is determined that 500 W of electric power is insufficient (500 W of electric power is supplied from the storage battery to each house H) in the second state, the discharge power of the storage battery is 501 W using the power generation efficiency. I presume that there is. According to this, since the EMS 40 can accurately estimate the discharge power of the storage battery in consideration of the discharge efficiency, the estimated integrated discharge amount B1, B2, B3 when the storage battery's discharge power and the generated power are combined and used alone. Can be calculated accurately.

The EMS 40 calculates the estimated integrated discharge amounts B1, B2, and B3 when used alone by appropriately integrating the discharged powers estimated as described above when used alone.

Hereinafter, a specific example of the procedure for calculating the estimated integrated discharge amounts B1, B2, and B3 when used alone will be described with reference to FIGS. 3 and 4. In the following, for convenience of explanation, the estimated integrated discharge amounts B1, B2, and B3 when used alone in a certain day will be calculated.

As for the power consumption shown in FIG. 3A, the morning time zone (time zone around 7 o'clock) and the night time zone (time zone around 19:00) are larger than the other time zones. Further, the generated power shown in FIG. 3B gradually increases from the sunrise time (before 7 o'clock), gradually decreases after peaking at around 12 o'clock, and becomes 0 at the sunset time (before 19:00). ..

FIG. 4 is a graph in which the power consumption and the generated power shown in FIG. 3 are superimposed. As shown in FIG. 4, the power consumption is larger than the generated power in the time zone T1 from about 0:00 to 9:00 and the time zone T3 from about 15:00 to 24:00. On the other hand, in the time zone (time zone from about 9:00 to 15:00) T2 between the time zone T1 and the time zone T3, the power consumption is equal to or less than the generated power.

In this case, the EMS 40 determines that it is in the first state in the time zone T2. Then, how much the EMS 40 outputs the generated power of each photovoltaic power generation system 30 (region R2 shown by diagonal lines in FIG. 4) in the time zone T2 by the estimation procedure in the first state as described above. To estimate. As a result, the EMS 40 estimates the discharge power when used alone in the time zone T2.

On the other hand, the EMS 40 determines that it is in the second state in the time zones T1 and T3. Then, the EMS 40 is insufficient only with the generated power of each photovoltaic power generation system 30 (regions R11 and R31 shown by diagonal lines in FIG. 4) in the time zones T1 and T3 due to the estimation procedure in the second state as described above. The discharge power of the storage battery is estimated with respect to the power (regions R12 and R32 shown by diagonal lines in FIG. 4). Then, the EMS 40 estimates that the total power of the discharge power of the storage battery and the power generated by each solar power generation system 30 is the discharge power when used alone in the time zones T1 and T3.

The EMS 40 appropriately integrates the discharge power during single use in the time zones T1 to T3 estimated as described above to calculate the estimated integrated discharge amounts B1, B2, and B3 during single use in a certain day.

As shown in FIG. 2, when the process of step S30 is completed, the EMS 40 shifts to step S40.

In step S40, the EMS 40 sets the discharge priority of the first storage battery system 21, the second storage battery system 22, and the third storage battery system 23. At this time, the EMS 40 subtracts the estimated integrated discharge amounts B1, B2, and B3 at the time of single use from the integrated discharge amounts A1, A2, and A3 at the time of power interchange. Then, the EMS 40 sets the discharge priority in order from the one with the smallest subtraction result (so that the smaller one is higher). When the process of step S40 is completed, the EMS 40 ends the discharge priority setting process.

When the EMS 40 finishes the discharge priority setting process, the EMS 40 discharges the storage battery system 20 in order from the one having the highest discharge priority according to the power consumption of each house H. More specifically, the EMS 40 first discharges the storage battery system 20 having the highest discharge priority. Further, the EMS 40 discharges the storage battery system 20 whose discharge priority is set to the second place when the power consumption of each house H cannot be covered by the power from the first-ranked storage battery system 20 alone. Further, the EMS 40 discharges the storage battery system 20 whose discharge priority is set to the third place when the power consumption of each house H cannot be covered by the power from the first and second storage battery systems 20.

As described above, when the power consumption of each house H cannot be covered, the EMS 40 starts discharging from the storage battery system 20 having a discharge priority one lower than that of the storage battery system 20 (where discharging has started). The process is repeated. In this way, with respect to the power consumption of each house H, discharge is sequentially started from the storage battery system 20 in which the discharge priority is set higher. As a result, the EMS 40 preferentially discharges the storage battery system 20 having a higher discharge priority. Further, the storage battery system 20 whose discharge has started performs a load follow-up operation based on the detection result of the sensor of the corresponding sensor unit 10.

Hereinafter, a specific example of the discharge priority processing will be described with reference to FIGS. 5 to 8.

FIG. 5 shows information on the amount of electric power on the day (first day) when the first storage battery system 21, the second storage battery system 22, and the third storage battery system 23 are installed. As shown in FIG. 5, the discharge amounts (integrated discharge amounts at the time of power interchange) on the day of the first storage battery system 21, the second storage battery system 22, and the third storage battery system 23 are 4kWh, 2kWh, and 0kWh, respectively. On the first day, the integrated discharge amounts A1, A2, and A3 at the time of power interchange of the first storage battery system 21, the second storage battery system 22, and the third storage battery system 23 are the same values as the discharge amounts of the day (respectively). Step S10).

The cumulative power consumption of the first house H1, the second house H2, and the third house H3 on the day is 1kWh, 2kWh, and 3kWh, respectively. The EMS 40 can obtain the integrated power consumption of the day by integrating the power consumption of the day (see FIG. 3A). Further, the EMS 40 can obtain the integrated power consumption up to the current day by adding the integrated power consumption up to the previous day to the integrated power consumption amount up to the current day. In the following, the integrated power consumption up to the day (from the time of installation of each storage battery system 20 to the day) in the first house H1, the second house H2, and the third house H3 are referred to as "integrated power consumption E1" and "integrated power consumption E1", respectively. It is referred to as "integrated power consumption E2" and "integrated power consumption E3". On the first day, the integrated power consumption E1, E2, and E3 of the first storage battery system 21, the second storage battery system 22, and the third storage battery system 23 are the same values as the integrated power consumption of the day, respectively.

In the following, for the sake of explanation, the calculation of the estimated integrated discharge amounts B1, B2, and B3 when used alone is simplified, and the estimated integrated discharge amounts B1, B2, and B3 when used alone are the integrated power consumption E1 respectively. -It is assumed that the values are the same as E2 and E3. Therefore, in FIG. 5, the estimated integrated discharge amounts B1, B2, and B3 when used alone are 1 kWh, 2 kWh, and 3 kWh, respectively (steps S20 and S30).

In the above state, the EMS 40 subtracts the estimated integrated discharge amounts B1, B2, and B3 at the time of single use from the integrated discharge amounts A1, A2, and A3 at the time of power interchange. As a result, the EMS 40 obtains +3 kWh as a subtraction result of the first house H1 (integrated discharge amount A1-estimated integrated discharge amount B1, cumulative value AB shown in FIG. 5). In the first house H1, the subtraction result is a positive value (the integrated discharge amount A1 at the time of power interchange exceeds the estimated integrated discharge amount B1 at the time of single use), so it is assumed that the first house H1 is used alone. It can be seen that, compared to the case, more discharge opportunities are obtained (profitable) due to the interchange of electric power.

Further, the EMS 40 obtains ± 0 kWh as a subtraction result of the second house H2 (integrated discharge amount A2-estimated integrated discharge amount B2). From this result, it can be seen that in the second house H2, the discharge opportunity does not change (no loss or gain) even if it is used alone.

Further, the EMS 40 obtains -3kWh as a subtraction result of the third house H3 (integrated discharge amount A3-estimated integrated discharge amount B3). In the third house H3, the subtraction result is a negative value (the integrated discharge amount A3 at the time of power interchange is lower than the estimated integrated discharge amount B3 at the time of single use), so it is assumed that the third house H3 is used alone. Compared with the case, it can be seen that the discharge opportunity is reduced (loss) due to the interchange of electric power.

The EMS 40 sets the discharge priority on the second day (next day) according to the subtraction results (+3 kWh, ± 0 kWh, -3 kWh) of the first house H1, the second house H2, and the third house H3 (step S40). .. At this time, the EMS 40 sets the third storage battery system 23 owned by the third housing H3 (-3kWh) having the smallest subtraction result to the first place in the discharge priority, and the second housing H2 (the second housing H2) having the next smallest subtraction result. The second storage battery system 22 owned by ± 0kWh) is set to the second place in the discharge priority, and the first storage battery system 21 owned by the first housing H1 (+3kWh) having the largest subtraction result is set to the third place in the discharge priority. Set.

On the second day, the EMS 40 discharges the first storage battery system 21, the second storage battery system 22, and the third storage battery system 23 based on the discharge priorities set as described above. That is, on the second day, the EMS 40 starts discharging from the third storage battery system 23 having the highest discharge priority, and the power from the third storage battery system 23 alone cannot cover the power consumption of each house H. , Starts discharging the second storage battery system 22 having the second highest discharge priority, and starts discharging the first storage battery system 21 having the third highest discharge priority when the power consumption of each house H cannot be covered. ..

As a result, on the second day, the EMS 40 preferentially discharges the third storage battery system 23 of the third house H3 (a house that has lost compared to the case where it is assumed to be used alone).

FIG. 6 shows information on the amount of electric power discharged on the second day as described above.

As shown in FIG. 6, on the second day, the first storage battery system 21 whose discharge priority was set to the third place was not discharged preferentially, and as a result, the discharge amount was smaller than that on the first day, and the discharge amount was reduced on that day. The amount of discharge is 0 kWh. Therefore, the integrated discharge amount A1 of the first storage battery system 21 on the second day is 4 kWh, which is the sum of the integrated discharge amount A1 (4 kWh) on the first day and the discharge amount (0 kWh) on the current day. Further, the integrated power consumption on the day of the first house H1 is 1 kWh. Therefore, the integrated power consumption E1 of the first house H1 on the second day is 2kWh, which is the sum of the integrated power consumption E1 (1kWh) on the first day and the integrated power consumption (1kWh) on the current day. Further, the estimated integrated discharge amount B1 when the first storage battery system 21 is used alone on the second day is the same value (2kWh) as the integrated power consumption amount E1 of the first house H1 on the second day. Therefore, the subtraction result of the first house H1 (integrated discharge amount A1-estimated integrated discharge amount B1) is + 2kWh.

As described above, on the second day, the EMS 40 lowers the discharge priority of the first storage battery system 21 in which the subtraction result (+3 kWh) of the previous day (first day) is larger than that of the other storage battery systems 20, thereby lowering the discharge amount. (Increase in integrated discharge amount A1) can be reduced to reduce the subtraction result on the second day from +3 kWh to +2 kWh. As a result, the integrated discharge amount A1 can be brought closer to the estimated integrated discharge amount B1.

Further, the second storage battery system 22 in which the discharge priority is set to the second place is discharged with some priority, and as a result, the discharge amount on the day is 2 kWh. Therefore, the integrated discharge amount A2 of the second storage battery system 22 on the second day is 4kWh, which is the sum of the integrated discharge amount A2 (2kWh) on the first day and the integrated discharge amount (2kWh) on the current day. Further, the integrated power consumption on the day of the second house H2 is 2 kWh. Therefore, the integrated power consumption E2 of the second house H2 on the second day is 4kWh, which is the sum of the integrated power consumption E2 (2kWh) on the first day and the integrated power consumption (2kWh) on the current day. Further, the estimated integrated discharge amount B2 when the second storage battery system 22 is used alone on the second day is the same value (4kWh) as the integrated power consumption amount E2 of the second housing H2 on the second day. Therefore, the subtraction result of the second house H2 (integrated discharge amount A2-estimated integrated discharge amount B2) is ± 0 kWh.

Further, as a result of preferentially discharging the third storage battery system 23 in which the discharge priority is set to the first place, the discharge amount is larger than that on the first day, and the discharge amount on that day is 4 kWh. Therefore, the integrated discharge amount A3 of the third storage battery system 23 on the second day is 4kWh, which is the sum of the integrated discharge amount A3 (0kWh) on the first day and the integrated discharge amount (4kWh) on the current day. Further, the integrated power consumption on the day of the third house H3 is 3 kWh. Therefore, the integrated power consumption E3 of the third house H3 on the second day is 6kWh, which is the sum of the integrated power consumption E3 (3kWh) on the first day and the integrated power consumption (3kWh) on the current day. Further, the estimated integrated discharge amount B3 when the third storage battery system 23 is used alone on the second day is the same value (6kWh) as the integrated power consumption amount E3 of the third house H3 on the second day. Therefore, the subtraction result of the third house H3 (integrated discharge amount A3-estimated integrated discharge amount B3) is -2kWh.

As described above, on the second day, the EMS 40 discharges by increasing the discharge priority of the third storage battery system 23 in which the subtraction result (-3kWh) of the previous day (first day) is smaller than that of the other storage battery systems 20. The amount (increase in the integrated discharge amount A3) can be increased to increase the subtraction result on the second day from -3kWh to -2kWh. As a result, the integrated discharge amount A3 can be brought closer to the estimated integrated discharge amount B3.

On the second day, the subtraction result changed from the first day, but the magnitude relationship between the houses H did not change. Therefore, as in the first day, the EMS 40 sets the third storage battery system 23 to the first discharge priority, the second storage battery system 22 to the second discharge priority, and the first storage battery system 21. Set to the third place in the discharge priority.

FIG. 7 shows information on the amount of electric power discharged on the third day based on the discharge priority set as described above.

As shown in FIG. 7, in the first storage battery system 21 in which the discharge priority is set to the third place on the third day, the discharge amount on the day is 0 kWh as in the second day. Therefore, the integrated discharge amount A1 of the first storage battery system 21 on the third day is 4kWh, which is the sum of the integrated discharge amount A1 (4kWh) on the second day and the discharge amount (0kWh) on the current day. Further, the integrated power consumption on the day of the first house H1 is 1 kWh. Therefore, the integrated power consumption E1 of the first house H1 on the third day is 3kWh, which is the sum of the integrated power consumption E1 (2kWh) on the second day and the integrated power consumption (1kWh) on the current day. Further, the estimated integrated discharge amount B1 when the first storage battery system 21 is used alone on the third day is the same value (3kWh) as the integrated power consumption amount E1 of the first house H1 on the third day. Therefore, the subtraction result of the first house H1 (integrated discharge amount A1-estimated integrated discharge amount B1) is + 1kWh.

As described above, the EMS 40 sets the discharge priority of the first storage battery system 21 in which the subtraction result (+ 2kWh) of the previous day (2nd day) is larger than that of the other storage battery systems 20 even on the 3rd day following the 2nd day. By lowering it, the subtraction result on the third day can be further reduced.

Further, in the second storage battery system 22 in which the discharge priority is set to the second place, the discharge amount on the day is 2 kWh as in the second day. Therefore, the integrated discharge amount A2 of the second storage battery system 22 on the third day is 6 kWh, which is the sum of the integrated discharge amount A2 (4 kWh) on the second day and the discharge amount (2 kWh) on the current day. Further, the integrated power consumption on the day of the second house H2 is 2 kWh. Therefore, the integrated power consumption E2 of the second house H2 on the third day is 6kWh, which is the sum of the integrated power consumption E2 (4kWh) on the second day and the integrated power consumption (2kWh) on the current day. Further, the estimated integrated discharge amount B2 when the second storage battery system 22 is used alone on the third day is the same value (6kWh) as the integrated power consumption amount E2 of the second housing H2 on the third day. Therefore, the subtraction result of the second house H2 (integrated discharge amount A2-estimated integrated discharge amount B2) is ± 0 kWh.

Further, in the third storage battery system 23 in which the discharge priority is set to the first place, the discharge amount on the day is 4 kWh as in the second day. Therefore, the integrated discharge amount A3 of the third storage battery system 23 on the third day is 8 kWh, which is the sum of the integrated discharge amount A3 (4 kWh) on the second day and the discharge amount (4 kWh) on the current day. Further, the integrated power consumption on the day of the third house H3 is 3 kWh. Therefore, the integrated power consumption E3 of the third house H3 on the third day is 9kWh, which is the sum of the integrated power consumption E3 (6kWh) on the second day and the integrated power consumption (3kWh) on the current day. Further, the estimated integrated discharge amount B3 when the third storage battery system 23 is used alone on the third day is the same value (9kWh) as the integrated power consumption amount E3 of the third house H3 on the third day. Therefore, the subtraction result of the third house H3 (integrated discharge amount A3-estimated integrated discharge amount B3) is -1kWh.

In this way, the EMS 40 is subtracted on the third day by increasing the discharge priority of the third storage battery system 23, which has a small subtraction result on the previous day (second day), even on the third day following the second day. The results can be further increased.

On the third day, the subtraction result changed from the second day, but the magnitude relationship between the houses H did not change. Therefore, as in the second day, the EMS 40 sets the third storage battery system 23 to the first discharge priority, the second storage battery system 22 to the second discharge priority, and the first storage battery system 21. Set to the third place in the discharge priority.

FIG. 8 shows information on the amount of electric power discharged on the fourth day based on the discharge priority set as described above.

As shown in FIG. 8, in the first storage battery system 21 in which the discharge priority is set to the third place on the fourth day, the discharge amount on the day is 0 kWh as in the third day. Therefore, the integrated discharge amount A1 of the first storage battery system 21 on the 4th day is 4kWh, which is the sum of the integrated discharge amount A1 (4kWh) on the 3rd day and the discharge amount (0kWh) on the current day. Further, the integrated power consumption on the day of the first house H1 is 1 kWh. Therefore, the integrated power consumption E1 of the first house H1 on the 4th day is 4kWh, which is the sum of the integrated power consumption E1 (3kWh) on the 3rd day and the integrated power consumption (1kWh) on the current day. Further, the estimated integrated discharge amount B1 when the first storage battery system 21 is used alone on the 4th day is the same value (4kWh) as the integrated power consumption amount E1 of the first house H1 on the 4th day. Therefore, the subtraction result of the first house H1 (integrated discharge amount A1-estimated integrated discharge amount B1) is ± 0 kWh.

In this way, the EMS 40 reduces the subtraction on the 4th day by lowering the discharge priority of the first storage battery system 21, which has a large subtraction result on the previous day (3rd day), even on the 4th day following the 3rd day. The result can be further reduced to ± 0 kWh.

Further, in the second storage battery system 22 in which the discharge priority is set to the second place, the discharge amount on the day is 2 kWh as in the third day. Therefore, the integrated discharge amount A2 of the second storage battery system 22 on the 4th day is 8kWh, which is the sum of the integrated discharge amount A2 (6kWh) on the 3rd day and the discharge amount (2kWh) on the current day. Further, the integrated power consumption on the day of the second house H2 is 2 kWh. Therefore, the integrated power consumption E2 of the second house H2 on the 4th day is 8kWh, which is the sum of the integrated power consumption E2 (6kWh) on the 3rd day and the integrated power consumption (2kWh) on the current day. Further, the estimated integrated discharge amount B2 when the second storage battery system 22 is used alone on the 4th day is the same value (8kWh) as the integrated power consumption amount E2 of the second housing H2 on the 4th day. Therefore, the subtraction result of the second house H2 (integrated discharge amount A2-estimated integrated discharge amount B2) is ± 0 kWh.

Further, in the third storage battery system 23 in which the discharge priority is set to the first place, the discharge amount on the day is 4 kWh as in the third day. Therefore, the integrated discharge amount A3 of the third storage battery system 23 on the 4th day is 12kWh, which is the sum of the integrated discharge amount A3 (8kWh) on the 3rd day and the discharge amount (4kWh) on the current day. Further, the integrated power consumption on the day of the third house H3 that owns the third storage battery system 23 is 3 kWh. Therefore, the integrated power consumption E3 of the third house H3 on the 4th day is 12kWh, which is the sum of the integrated power consumption E3 (9kWh) on the 3rd day and the integrated power consumption (3kWh) on the current day. Further, the estimated integrated discharge amount B3 when the third storage battery system 23 is used alone on the fourth day is the same value (12kWh) as the integrated power consumption amount E3 of the third house H3 on the third day. Therefore, the subtraction result of the third house H3 (integrated discharge amount A3-estimated integrated discharge amount B3) is ± 0 kWh.

In this way, the EMS 40 is subtracted on the 4th day by increasing the discharge priority of the third storage battery system 23, which has a small subtraction result on the previous day (3rd day), even on the 4th day following the 3rd day. The result can be further increased to ± 0 kWh.

As described above, according to the EMS 40, by using the integrated discharge amounts A1, A2, A3 at the time of power interchange and the estimated integrated discharge amounts B1, B2, B3 at the time of single use (steps S30, S40), the power interchange Therefore, it is possible to set the discharge priority in consideration of the profit and loss generated in each house H. More specifically, the difference between the integrated discharge amounts A1, A2, and A3 and the estimated integrated discharge amounts B1, B2, and B3 can be used to determine whether or not the loss or gain has occurred in each house H due to the interchange of electric power. If the discharge priority is set based on the determination result, the discharge priority of the storage battery system 20 (the third storage battery system 23 of the third house H3 in FIG. 9) owned by the house H that has lost due to the interchange of electric power is set high. Then, the storage battery system 20 owned by another house H can be discharged preferentially. As a result, the amount of discharge of the storage battery system 20 owned by the house H, which has been damaged by the interchange of electric power, can be increased. In this way, it is possible to make it possible for the house H, which has been damaged by the interchange of electric power, to obtain a higher charge than the other houses H.

Further, as compared with the case of single use, the discharge priority of the storage battery system 20 owned by the house H (the first storage battery system 21 of the first house H1 in FIG. 9) obtained by the interchange of electric power is lowered. The amount of discharge can be reduced. As a result, it is possible to prevent the housing H, which has gained through the accommodation of electric power, from being excessively charged (excessively with respect to its own power consumption).

As described above, the EMS 40 can suppress an increase or decrease in the integrated discharge amounts A1, A2, and A3 of each storage battery system 20 as compared with the case where it is assumed to be used alone, and thus suppresses the occurrence of loss or gain in each house H. It is possible to prevent an unfair situation from occurring.

Further, the EMS 40 can set the optimum priority by obtaining the difference between the integrated discharge amounts A1, A2, and A3 and the estimated integrated discharge amounts B1, B2, and B3 (steps S30 and S40). More specifically, the EMS 40 can determine whether or not the profit or loss has occurred according to the actual situation of each house H by obtaining the difference. This makes it possible to accurately determine whether or not each house H has gained or lost due to the interchange of electric power. Further, the EMS 40 can set the discharge priority according to the actual situation of each house H by setting the discharge priority according to the difference (step S40). In this way, the optimum discharge priority can be set.

Further, the EMS 40 uses a plurality of parameters related to the charge / discharge of the storage battery (device specifications of the storage battery, specifically, charge / discharge efficiency, maximum charge / discharge amount, etc.) to obtain an estimated integrated discharge amount B1, B2, B3 when used alone. It is calculated (step S30). As a result, the estimated integrated discharge amounts B1, B2, and B3 when used alone can be accurately calculated according to the actual situation of the storage battery.

Further, in the specific example using FIGS. 5 to 8, the calculation of the estimated integrated discharge amounts B1, B2, and B3 at the time of single use is simplified, and the estimated integrated discharge amounts B1, B2, and B3 are the integrated power consumption, respectively. It was assumed that the values were the same as the quantities E1, E2, and E3. By replacing the estimated integrated discharge amounts B1, B2, and B3 with the integrated power consumption amounts E1, E2, and E3 in this way, the EMS 40 does not have to consider the power generation amounts D1, D2, D3, etc. of the photovoltaic power generation system 30. Therefore, the discharge priority can be easily set.

Further, the EMS 40 sets the discharge priority so that the subtraction result of each house H does not become less than 0 (the integrated discharge amounts A1, A2, and A3 do not fall below the estimated integrated discharge amounts B1, B2, and B3). ing. As a result, it is possible to prevent the inhabitants of each house H from feeling dissatisfied with the fact that they could discharge more electric power when they were used alone (it would have been better if the electric power had not been accommodated).

As described above, the power supply system 1 according to the present embodiment is provided so as to correspond to a plurality of houses H (customers) having a load, and the discharged electric power is used regardless of the correspondence relationship with the house H. Discharge of the plurality of storage battery systems 20 is performed based on the plurality of storage battery systems 20 (storage batteries) capable of supplying the load of the plurality of houses H and the discharge priority (priority) regarding the discharge of the plurality of storage battery systems 20. It comprises an EMS 40 (control unit) to be controlled, and the EMS 40 is based on the integrated discharge amounts A1, A2, A3 of the plurality of storage battery systems 20 and the power consumption amounts C1, C2, C3 of the plurality of houses H. The discharge priority is set.

With such a configuration, it is possible to prevent an unfair situation from occurring. Specifically, the EMS 40 can acquire the integrated power consumption amounts E1, E2, and E3 from the power consumption amounts C1, C2, and C3. The EMS40 is a house in which the integrated electric energy A1, A2, A3 is smaller than the integrated electric energy E1, E2, E3 due to the integrated electric energy E1, E2, E3 and the integrated electric energy A1, A2, A3. It is possible to determine the housing H (third housing H3 shown in FIG. 5) that is losing compared to the case where it is assumed to be used alone. If the discharge priority is set based on the determination result, the storage battery system 20 of the damaged house H can be discharged preferentially to increase the integrated discharge amounts A1, A2, and A3. As a result, the integrated discharge amounts A1, A2, and A3 can be adjusted so as not to cause a loss as compared with the case where they are used alone, so that it is possible to suppress the occurrence of an unfair situation.

Further, the EMS 40 is an estimated integrated discharge amount estimated to be discharged by the storage battery system 20 when it is assumed that only the storage battery system 20 corresponding to the house H is discharged with respect to the load of the house H. B1, B2, and B3 are calculated based on the power consumption amounts C1, C2, and C3, and based on the difference between the integrated discharge amounts A1, A2, and A3 and the estimated integrated discharge amounts B1, B2, and B3. It sets the discharge priority.

With such a configuration, the house H lost due to the interchange of electric power can be accurately grasped, so that the discharge priority can be optimized.

Further, the EMS 40 calculates the estimated integrated discharge amounts B1, B2, and B3 based on the specification information of the storage battery system 20 (device specifications of the storage battery) and the power consumption amounts C1, C2, and C3.

With this configuration, the estimated integrated discharge amounts B1, B2, and B3 can be calculated accurately. This makes it possible to optimize the discharge priority.

Further, a plurality of photovoltaic power generation systems 30 (power generation units) provided so as to correspond to the plurality of houses H and capable of generating power by using natural energy are further provided, and the EMS 40 has the power consumption C1. The estimated integrated discharge amounts B1, B2, and B3 are calculated based on C2 and C3, the specification information of the storage battery system 20, and the power generation amounts D1, D2, and D3 of the photovoltaic power generation system 30.

With this configuration, the estimated integrated discharge amounts B1, B2, and B3 can be calculated accurately even if the photovoltaic power generation system 30 is provided.

The storage battery system 20 according to the present embodiment is an embodiment of the storage battery according to the present invention.
Further, the EMS 40 according to the present embodiment is an embodiment of the control unit according to the present invention.
Further, the solar power generation system 30 according to the present embodiment is an embodiment of the power generation unit according to the present invention.

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

For example, in the present embodiment, the power supply system 1 is provided in an apartment house, but the present invention is not limited to this, and may be provided in, for example, an office or the like.

Further, in the present embodiment, the number of units of each house H is set to 3, but the number is not limited to this, and any number of 2 or more units can be used.

Further, the configuration of the power supply system 1 is not limited to the present embodiment, and may be a configuration including a hybrid storage battery system in which a storage battery and a solar power generation unit are separately connected to the power conditioner.

Further, in the present embodiment, the number of the storage battery system 20 and the solar power generation system 30 is assumed to be three, but the number is not limited to this, and any number may be used according to the number of units in each house H. be able to.

Further, the power generation unit is a solar power generation system 30 that uses sunlight to generate power, but the power generation unit is limited to this if it uses natural energy (for example, hydraulic power or wind power) to generate power. It's not something.

Further, the electric power supply system 1 may be provided with at least a storage battery system 20 as a device for supplying electric power to each house H, and does not necessarily have to be provided with the solar power generation system 30.

Further, the storage battery system 20 is arranged in series with the distribution line L (so as to line up from the upstream side to the downstream side), but the arrangement of the storage battery system 20 is not limited to this, for example. They may be arranged in parallel with each other in the middle of the distribution line L.

Further, the EMS 40 may calculate the estimated integrated discharge amounts B1, B2, and B3 when used alone, in consideration of the control regarding the operation of the storage battery. That is, in the present embodiment, the operation of the storage battery is controlled so that the storage battery is fully charged in the midnight time zone. Therefore, the EMS 40 determines that the storage battery does not discharge (discharge power is 0) in the midnight time zone, and estimates that the discharge power when used alone in the midnight time zone is 0. According to this, the EMS 40 can accurately calculate the estimated integrated discharge amounts B1, B2, and B3 when used alone, in consideration of the control regarding the operation of the storage battery.

Further, the EMS 40 does not necessarily have to use the device specifications of the storage battery when calculating the estimated integrated discharge amounts B1, B2, and B3 when used alone. In this case, for example, in the first state where the power consumption of each house H is equal to or less than the power generation power of each solar power generation system 30, the EMS 40 is charging all the power generation surplus with respect to the power consumption, or the above-mentioned. It may be judged that all the surplus generated power is reverse power flow. If it is determined that the battery is fully charged, it may be estimated that the discharge power in the first state when used alone is the same as the power consumption. Further, if it is determined that all the power is reverse power flow, it may be estimated that the discharge power at the time of single use in the first state is the same power as the generated power. Further, the EMS 40 may determine that the power consumption of each house H is all covered by the discharge of the storage battery in the second state where the power consumption of each house H is larger than the power generated by each solar power generation system 30. In this case, it may be estimated that the discharge power at the time of single use in the second state is the same power as the power consumption.

Further, the EMS 40 may be any one that sets the discharge priority in consideration of the loss and gain caused in each house H due to the interchange of electric power, and is not necessarily discharged by using the estimated integrated discharge amounts B1, B2, and B3 at the time of single use. There is no need to set priorities. The EMS 40 may set the discharge priority order by using, for example, the integrated power consumption E1, E2, and E3 of each house H.

Further, in the present embodiment, it is assumed that the priority is set by the EMS 40, but the device for setting the priority is not limited to this, and various devices can be used.

1 Power supply system 20 Storage battery system (storage battery)
40 EMS (control unit)
A1, A2, A3 Integrated discharge amount C1, C2, C3 Power consumption H Housing (customer)

Claims (3)

A plurality of storage batteries provided so as to correspond to a plurality of consumers having a load and capable of supplying the discharged electric power to the load of the plurality of consumers regardless of the correspondence relationship with the consumers.
A control unit that controls the discharge of the plurality of storage batteries based on the priority regarding the discharge of the plurality of storage batteries.
Equipped with
The control unit
The priority is set based on the integrated discharge amount of the plurality of storage batteries and the power consumption amount of the plurality of consumers .
Assuming that only the storage battery corresponding to the consumer is discharged with respect to the load of the consumer, the estimated integrated discharge amount estimated that the storage battery is discharged is calculated based on the power consumption. death,
The priority is set based on the difference between the integrated discharge amount and the estimated integrated discharge amount.
The discharge priority is set so that the one having a small difference between the integrated discharge amount and the estimated integrated discharge amount is higher, and the storage battery having the higher discharge priority is preferentially discharged.
Power supply system. The control unit
The estimated integrated discharge amount is calculated based on the specification information of the storage battery and the power consumption amount.
The power supply system according to claim 1. It is further equipped with a plurality of power generation units that are provided to meet the above-mentioned multiple consumers and can generate power using natural energy.
The control unit
The estimated integrated discharge amount is calculated based on the power consumption amount, the specification information of the storage battery, and the power generation amount of the power generation unit.
The power supply system according to claim 2.

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