JP5995804B2 - Storage system management device and control target value determination method - Google Patents

Description

  The present invention relates to a storage system management device and a control target value determination method.

  In recent years, technologies relating to power management (hereinafter referred to as “energy management”) for supplying stable power according to power demand have been developed. As an example of this, a natural energy power generation facility, a private power generation facility, a power storage system, and the like arranged in a house, a building, and a town are networked and controlled according to power demand.

  One of the purposes of energy management is, for example, load leveling (hereinafter referred to as “peak shift”) in which electric power generated at night is used during the daytime when consumption is higher. By performing the peak shift, it is expected that the electricity cost will be reduced by reducing the influence on the system due to the power fluctuation of natural energy power generation and reducing the usage amount of contract power.

Patent Document 1 discloses an energy management system that can appropriately perform peak cutting even for a user who does not have specialized knowledge.
Specifically, in the energy management system described in Patent Document 1, the management server transmits a peak cut request for requesting peak suppression of energy demand to each customer. And when the energy management part provided in each of the consumer receives the peak cut request from the management server, the power consumption of the equipment, the AC output operation of the inverter part, and the charge / discharge part to satisfy the peak reduction target Controls the charging / discharging operation.

JP 2012-244665 A

In the energy management system described in Patent Document 1, a peak cut request, which is information that is a target of load leveling, is received from an electric power company, and control is performed based on the value.
However, since the energy management system cannot know in advance the peak value of the power demand for the day, it is necessary to determine a control target value related to the discharge of the storage battery necessary to achieve the peak reduction target. Conventionally, an administrator determines a control target value related to discharge of a storage battery based on an empirical rule or the like so far, and inputs the control target value to an energy management system. However, in such a method for determining the control target value, the control target value input by the administrator may be different and may not always be appropriate.

  The present invention has been made in view of such circumstances, and appropriately determines a control target value related to discharge of a storage battery, which is required to achieve a peak reduction target of power supplied from a commercial system. An object of the present invention is to provide a power storage system management device and a control target value determination method.

  In order to solve the above problems, the power storage system management apparatus and control target value determination method of the present invention employ the following means.

  A power storage system management device according to a first aspect of the present invention is a power storage system management device that is connected to a power generation device, a load, and a power transmission line connected to a commercial system and charges or discharges a storage battery. An input means for inputting a reduction target for the peak value of the power supplied from the grid; an underload power calculation means for calculating an underload power that is a difference between the power consumption of the load and the generated power by the power generator; Candidate value deriving means for deriving a candidate value that can be a control target value of the discharge amount from the storage battery based on the reduction target and the maximum value of the underload power at a predetermined time before the current time, and a predetermined time before the current time Supply power peak deriving means for deriving a peak value of power supplied from the commercial system in the case where the candidate value exceeds the peak value, the candidate value is determined as the control value. Determining the value, if the candidate value is less than the peak value, and a determination means for determining the peak value as the control target value.

  According to this configuration, the power storage system is connected to the power generation device, the load, and the power transmission line connected to the commercial system, and charges or discharges the storage battery.

  When there is insufficient load power, which is the difference between the power generated by the power generation device and the power consumption of the load, power is supplied from the commercial system. And the discharge of a storage battery is performed for the purpose of reduction with respect to the peak value of the electric power supplied from a commercial system. For this reason, the reduction target for the peak value of the power supplied from the commercial system is input to the input means. Specifically, the input unit receives an input of a reduction target from a higher system, for example.

The storage battery system discharges from the storage battery based on the control target value. The control target value is determined based on the reduction target.
For this purpose, a candidate value that can be a control target value is calculated by the candidate value deriving means based on the reduction target and the maximum value of the load shortage power at a predetermined time before the present time. Further, the peak value of the power supplied from the commercial system at a predetermined time before the present is derived by the supplied power peak deriving means. The predetermined time before the present is, for example, 24 hours before the present.

  And when a candidate value exceeds a peak value by a determination means, a candidate value is determined as a control target value of a storage battery, and when a candidate value is below a peak value, a peak value is determined as a control target value of a storage battery. That is, the storage battery control target value has the peak value derived by the supply power peak deriving means as the lower limit.

  The reason why the peak value is determined as the control target value when the candidate value is equal to or lower than the peak value is as follows. The peak value of the power supplied from the commercial system is a value (for example, the value of contract power) that has already been approved for supply from the commercial system. For this reason, even if the storage battery is discharged so as to reduce the peak value that has already been approved, the peak cannot be substantially reduced. In addition, there is a possibility that the charging rate of the storage battery is unnecessarily lowered and the storage battery cannot be discharged when necessary. That is, the discharge of the storage battery for reducing the peak value that has already been supplied is not appropriate.

  As described above, according to this configuration, it is possible to appropriately determine the control target value related to the discharge of the storage battery, which is required to achieve the peak reduction target of the power supplied from the commercial system.

  In said 1st aspect, it is set as the discharge mode which discharges the said storage battery when the said load insufficient power exceeds the said control target value, and when the said load insufficient power is below the said control target value, it is supplied from the said commercial system. It is preferable to include a selection unit that selects an operation mode of the power storage system by setting a charging mode in which electric power is charged in the storage battery.

  According to this configuration, the operation mode of the power storage system can be appropriately selected.

  In the first aspect, it is preferable that the selection unit selects a stop mode in which the inverter of the storage battery is in a standby state or the supply of power to the inverter is stopped when the storage battery is not charged or discharged.

  According to this structure, the power loss which arises by providing a storage battery can be reduced.

  A control target value determination method according to the second aspect of the present invention is a control target value determination method for a power storage system that is connected to a power transmission device, a load, and a power transmission line connected to a commercial system and charges or discharges a storage battery. A first step of calculating an underload power that is a difference between the power consumption of the load and the power generated by the power generation device, a reduction target for a peak value of power supplied from the commercial grid, and a predetermined time before the current time A candidate value that can be a control target value of the discharge amount from the storage battery is derived based on the maximum value of the underload power, and a peak value of the power supplied from the commercial system at a predetermined time before the present is derived. In the second step, when the candidate value exceeds the peak value, the candidate value is determined as the control target value, and when the candidate value is equal to or less than the peak value, the peak value is determined as the control target value. And a third step of determining a value, the.

  According to the present invention, there is an excellent effect that it is possible to appropriately determine the control target value related to the discharge of the storage battery, which is required to achieve the peak reduction target of the electric power supplied from the commercial system.

It is a lineblock diagram of an electric power system concerning an embodiment of the present invention. It is a graph which shows the surplus electric power charge mode which concerns on embodiment of this invention. It is a graph which shows the discharge mode which concerns on embodiment of this invention. It is a graph which shows the charge mode which concerns on embodiment of this invention. It is a graph which shows the stop mode which concerns on embodiment of this invention. It is a functional block diagram which shows the electric constitution of the energy management system which concerns on embodiment of this invention. It is a graph which shows an example of the candidate target value concerning the embodiment of the present invention. It is a graph which shows an example of the electric power purchase peak value concerning the embodiment of the present invention. It is a flowchart which shows the flow of the control target value determination process which concerns on embodiment of this invention. It is a flowchart which shows the flow of the operation mode selection process which concerns on embodiment of this invention.

  Hereinafter, an embodiment of a power storage system management apparatus and control target value determination method according to the present invention will be described with reference to the drawings.

  FIG. 1 is a configuration diagram of a power system 12 including a power storage system 10 according to the present embodiment.

  The power storage system 10 is connected to a power transmission line 20 connected to the power generation device 14, the load 16, and the commercial system 18, and charges or discharges the storage battery 24 via the inverter 22. The power storage system 10 is connected to the commercial system 18 side compared to the power generation device 14 and the load 16.

  The power generation device 14 and the load 16 are provided in a town (town) or a building. The power generation device 14 is, for example, a power generation device (solar cell device, wind power generation device, or the like) using natural energy, a fuel cell, or the like. The load 16 is various electric devices that operate with electric power, such as street lamps and air conditioning and electric lights of buildings.

  In the power system 12, there is a case where insufficient load power is generated which is a difference between the power consumption of the load 16 and the power generated by the power generation device 14. In this case, discharge from the storage battery 24 and power supply from the commercial system 18 (hereinafter referred to as “purchased power”) are performed in order to cover the insufficient load power.

  The storage battery 24 has a plurality of cells connected in series or in parallel, and stores the generated power of the power generation device 14 or the purchased power from the commercial system 18.

  The inverter 22 converts the DC power of the storage battery 24 and the AC power of the commercial system 18.

The power storage system 10 includes a power storage system control device 26.
The power storage system control device 26 manages overall control of the power storage system 10, such as management of the state of the storage battery 24, output of commands related to charging or discharging of the storage battery 24 to the inverter 22, and switching of operation modes. The operation state of the storage battery 24 is, for example, the charging rate (State of Charge: SOC) of the storage battery 24, the temperature of the storage battery 24, the number of times the storage battery 24 is charged or discharged, and the like.

Further, near the connection point between the transmission line 20 and the commercial system 18, power detection units 28 </ b> A, 28 </ b> B, and 28 </ b> C that detect power (current) flowing through the transmission line 20 are provided.
The power detection unit 28 </ b> A detects the purchased power supplied to the power transmission line 20 and the power supplied from the power transmission line 20 to the commercial system 18.
The power detection unit 28 </ b> B detects power (discharge power) supplied from the power storage system 10 to the power transmission line 20 and power (charge power) supplied from the power transmission line 20 to the power storage system 10.
The power detection unit 28 </ b> C detects the power supplied from the power generation device 14 to the commercial system 18 or the power storage system 10 and the power supplied from the commercial system 18 or the power storage system 10 to the load 16.

  The operation of the power storage system 10 is managed by an energy management system (hereinafter referred to as “EMS”) 30.

  The EMS 30 receives the operation state of the storage battery 24 from the power storage system control device 26 as operation state information. The EMS 30 also includes power consumption information indicating the amount of power consumed by the load 16, power generation information indicating the amount of power generated by the power generation device 14, and power detection information that is a detection result by the power detection units 28A, 28B, and 28C. Receive.

The EMS 30 stores the received various information in the database 32 in time series, generates an operation mode command indicating the operation mode of the power storage system 10 based on the various information, and transmits the operation mode command to the power storage system control device 26.
Further, the EMS 30 receives a reduction target (hereinafter referred to as “peak reduction target value”) with respect to a peak value of purchased power that is power supplied from the commercial grid 18. The peak reduction target value is input from the host management system 34 that manages the commercial system 18. However, the present invention is not limited to this, and the peak reduction target value may be input to the EMS 30 by an administrator, for example.
In other words, the peak reduction target value is a leveling target value for the purchased power consumed by the load 16.

  Then, the EMS 30 generates a control target value for the amount of discharge from the storage battery 24. The control target value is determined based on the peak reduction target value. The determined control target value is output to power storage system control device 26.

Here, the operation mode of the power storage system 10 will be described with reference to FIGS.
The operation modes according to the present embodiment are a surplus power charging mode, a discharging mode, a charging mode, and a stop mode.
Note that when the power storage system control device 26 receives an operation mode command from the EMS 30 described later, the operation mode is switched in accordance with the operation mode command.

  In the surplus power charging mode, as shown in FIG. 2, surplus power that is generated by the power generation device 14 that has not been consumed by the load 16 is charged to the storage battery 24.

  In the discharge mode and the charge mode described below, the storage battery system controller 26 controls the discharge and charge of the storage battery 24 based on the control target value.

  In the discharge mode, as shown in FIG. 3, the storage battery 24 is discharged so that the power purchased to cover the insufficient load power is reduced. That is, the storage battery 24 is discharged to achieve the peak reduction target. Specifically, in the discharge mode, when the underload power exceeds the control target value, the difference between the underload power and the control target value is discharged from the storage battery 24 to reduce the peak value of the purchased power.

  The charging mode causes the storage battery 24 to be charged with the purchased power when the insufficient load power is equal to or less than the control target value. In the charging mode according to the present embodiment, as shown in FIG. 4, a time zone where the underload power is less than or equal to the control target value and the electricity rate is low, such as at night (for example, from 12:00 am to 5:00 am Until the storage battery 24 is charged.

In the stop mode, as shown in FIG. 5, the storage system 10 is stopped when the storage battery 24 is not charged or discharged.
The case where the storage battery 24 is not charged is a case where the power shortage is less than the control target value, the time when the electricity rate is not low, or the peak reduction is not achieved even if the storage battery 24 is discharged. That is, it is a case where none of the surplus power charging mode, the discharging mode, and the charging mode is selected as the operation mode.

  The stop of the power storage system 10 means that the inverter 22 is in a standby state or the supply of power to the inverter 22 is stopped. Thereby, stop mode can reduce the power loss which arises by providing the storage battery 24. FIG.

  Here, generation of a control target value by the EMS 30 will be described.

FIG. 6 is a functional block diagram showing an electrical configuration of the EMS 30 related to generation of the control target value. The EMS 30 includes, for example, a CPU (Central Processing Unit), a RAM (Random
Access Memory) and a computer-readable recording medium. A series of processes for realizing various functions is recorded on a recording medium or the like in the form of a program as an example, and the CPU reads the program into a RAM or the like to execute information processing / arithmetic processing. As a result, various functions are realized.

  The EMS 30 includes an input unit 40, an underload power calculation unit 42, a candidate target value derivation unit 44, a purchased power peak derivation unit 46, a control target value determination unit 48, and an operation mode selection unit 50.

  The input unit 40 receives an input of a peak reduction target value from the upper management system 34. The input peak reduction target value is output to the candidate target value deriving unit 44.

The underload power calculating unit 42 calculates the value of the underload power by subtracting the value of the generated power of the power generation device 14 from the value of the power consumption of the load 16 input to the EMS 30.
The underload power is calculated at predetermined time intervals and stored in the database 32 in time series.

The candidate target value deriving unit 44 derives a candidate value (hereinafter referred to as “candidate target value”) that can be a control target value based on the peak reduction target value and the maximum value of the load shortage power at a predetermined time before the current time. . The predetermined time before the present is, for example, 24 hours before the present. The underload power at a predetermined time before the current time is read from the database 32.
For example, when the peak reduction target value is 50% and the maximum value of insufficient load power is 300 kW, the candidate target value deriving unit 44 calculates the candidate target value as 150 kW.

  The derived candidate target value is output to the control target value determination unit 48.

FIG. 7 is a graph showing an example of candidate target values.
FIG. 7 is an example of the case where the maximum value of the underload power is always the current time. In such a case, the candidate target value changes with the time.

  The purchased power peak deriving unit 46 derives a peak value of purchased power (hereinafter referred to as “purchased power peak value”) for a predetermined time before the present time. The predetermined time before the present is, for example, 24 hours before the present. The purchased power for a predetermined time before the current time is read from the database 32.

  The derived purchased power peak value is output to the control target value determination unit 48.

  FIG. 8 is a graph showing an example of the purchased power peak value.

  The control target value determination unit 48 determines the candidate target value as the control target value when the candidate target value exceeds the purchased power peak value, and when the candidate target value is equal to or less than the purchased power peak value, the purchased power peak value. Is determined as a control target value. That is, the control target value of the storage battery 24 has the purchased power peak value as a lower limit.

The reason why the purchased power peak value is determined as the control target value when the candidate target value is equal to or less than the purchased power peak value is as follows.
The purchased power peak value is a value (for example, the value of contract power) that has already been approved for supply from the commercial grid 18. For this reason, even if the storage battery 24 is discharged so that the purchased power peak value that has already been supplied is made smaller, the peak is not substantially reduced. In addition, the charging rate of the storage battery 24 may be unnecessarily lowered, and the storage battery 24 may not be discharged when necessary. That is, the discharge of the storage battery 24 for reducing the purchased power peak value that has already been approved is not appropriate.

  The control target value determined by the control target value determination unit 48 is output to the operation mode selection unit 50.

  FIG. 9 illustrates a process of determining a control target value (hereinafter referred to as “control target value determination process”) executed by the candidate target value deriving unit 44, the purchased power peak deriving unit 46, and the control target value determining unit 48. It is a flowchart which shows a flow. The control target value determination process is executed, for example, every time the underload power is calculated.

  First, in step 100, information such as a value of insufficient load power and a value of purchased power is read from the database 32 for a predetermined time before the present time.

  In the next step 102, the candidate target value and the purchased power peak value are derived based on the information read from the database 32.

  In the next step 104, it is determined whether or not the candidate target value exceeds the purchased power peak value. If the determination is affirmative, the process proceeds to step 106. If the determination is negative, the process proceeds to step 108.

  In step 106, the candidate target value is determined as the control target value, and the control target value determination process is terminated.

  In step 108, the purchased power peak value is determined as the control target value, and the control target value determination process is terminated.

  After determining the control target value, the EMS 30 causes the operation mode selection unit 50 to perform a process of selecting an operation mode of the power storage system 10 (hereinafter referred to as “operation mode selection process”).

  FIG. 10 is a flowchart showing the flow of the operation mode selection process. The operation mode selection process is executed each time a control target value is input to the operation mode selection unit 50.

  First, in step 200, it is determined whether or not the current generated power of the power generator 14 is larger than the current power consumption of the load 16. If the determination is affirmative, the process proceeds to step 202. If the determination is negative, step 206 is performed. Migrate to

  In step 202, it is determined whether or not the storage battery 24 is in a chargeable state. If the determination is affirmative, the process proceeds to step 204 and the surplus power charging mode is selected as the operation mode. On the other hand, in the case of negative determination, the process proceeds to step 218 and the stop mode is selected as the operation mode. The case where the storage battery 24 cannot be charged is, for example, the case where the charge rate of the storage battery 24 is equal to or higher than the chargeable charge rate.

  In step 206, it is determined whether or not the current control target value is smaller than the current underload power. If the determination is affirmative, the process proceeds to step 208. If the determination is negative, the process proceeds to step 212.

  In step 208, it is determined whether or not the storage battery 24 is in a dischargeable state. If the determination is affirmative, the process proceeds to step 210 and the discharge mode is selected as the operation mode. On the other hand, in the case of negative determination, the process proceeds to step 218 and the stop mode is selected as the operation mode. The case where the storage battery 24 cannot be discharged is, for example, a case where the charge rate of the storage battery 24 is equal to or less than the chargeable charge rate.

  In step 212, it is determined whether or not the current time is a time zone in which the purchased power can be charged by the storage battery 24. If the determination is affirmative, the process proceeds to step 214. On the other hand, in the case of negative determination, the process proceeds to step 218 and the stop mode is selected as the operation mode.

  In step 214, it is determined whether or not the storage battery 24 is in a chargeable state. If the determination is affirmative, the process proceeds to step 216 and the charging mode is selected as the operation mode. On the other hand, in the case of negative determination, the process proceeds to step 218 and the stop mode is selected as the operation mode.

  The selected operation mode is output from the EMS 30 to the power storage system control device 26 as an operation mode command.

  As described above, the EMS 30 according to the present embodiment calculates the insufficient load power that is the difference between the power consumption of the load 16 and the power generated by the power generation device 14. Then, the EMS 30 derives a candidate target value that can be a control target value of the discharge amount from the storage battery 24, based on the reduction target for the purchased power peak value and the maximum value of the load shortage power at a predetermined time before the current time, The peak value of purchased power at a predetermined time before the present is derived. Thereafter, the EMS 30 determines the candidate target value as the control target value when the candidate target value exceeds the purchased power peak value, and determines the purchased power peak value as the control target when the candidate target value is equal to or less than the purchased power peak value. Determine as value.

  Thereby, the control target value regarding the discharge of the storage battery 24 required for achieving the peak reduction target of the electric power supplied from the EMS 30 and the commercial system 18 can be appropriately determined.

  As mentioned above, although this invention was demonstrated using the said embodiment, the technical scope of this invention is not limited to the range as described in the said embodiment. Various changes or improvements can be added to the above-described embodiment without departing from the gist of the invention, and embodiments to which the changes or improvements are added are also included in the technical scope of the present invention.

  The flow of various processes described in the above embodiment is also an example, and unnecessary steps may be deleted, new steps may be added, or the processing order may be changed within a range not departing from the gist of the present invention. Also good.

10 Power storage system 30 EMS
DESCRIPTION OF SYMBOLS 40 Input part 42 Underload electric power calculation part 44 Candidate target value derivation part 46 Purchased electric power peak derivation part 48 Control target value determination part 50 Operation mode selection part

Claims (4)

A power storage system management device connected to a power generation device, a load, and a power transmission line connected to a commercial system and charging or discharging a storage battery,
Input means for inputting a reduction target for the peak value of power supplied from the commercial system;
A load shortage power calculating means for calculating load shortage power that is a difference between power consumption of the load and power generated by the power generation device;
Candidate value deriving means for deriving a candidate value that can be a control target value for the amount of discharge from the storage battery based on the reduction target and the maximum value of the underload power at a predetermined time before the current time;
Supply power peak deriving means for deriving a peak value of power supplied from the commercial system at a predetermined time before the present time,
Determining means for determining the candidate value as the control target value when the candidate value exceeds the peak value, and determining the peak value as the control target value when the candidate value is equal to or less than the peak value;
A storage system management apparatus comprising:   When the underload power exceeds the control target value, the discharge mode is set to discharge the storage battery. When the underload power is equal to or less than the control target value, the power supplied from the commercial system is charged to the storage battery. The power storage system management apparatus according to claim 1, further comprising selection means for selecting an operation mode of the power storage system by setting the charging mode to be performed.   The storage device management apparatus according to claim 2, wherein, when the storage battery is not charged or discharged, the selection unit selects a stop mode in which the inverter of the storage battery is in a standby state or stops supplying power to the inverter. A control target value determination method for a power storage system that is connected to a power generation device, a load, and a power transmission line connected to a commercial system and charges or discharges a storage battery,
A first step of calculating a load shortage power that is a difference between the power consumption of the load and the power generated by the power generation device;
Based on the reduction target for the peak value of power supplied from the commercial grid and the maximum value of the insufficient load power for a predetermined time before the present, a candidate value that can be a control target value for the discharge amount from the storage battery is derived. A second step of deriving a peak value of electric power supplied from the commercial system at a predetermined time before the present time;
A third step of determining the candidate value as the control target value when the candidate value exceeds the peak value, and determining the peak value as the control target value when the candidate value is equal to or less than the peak value;
Control target value determination method including

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