JP2018157647A - Information processing apparatus, control device for power storage apparatus, electric power system, control method, and program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an information processing apparatus and a control device for a power storage apparatus which are capable of suppressing deterioration of a storage battery and stabilizing electric power in an electric power system.SOLUTION: The information processing apparatus comprises an operation unit that generates, on the basis of status data from a power storage apparatus, charging/discharging instruction data for instructing storage batteries included in the power storage apparatus to be charged or discharged. The power storage apparatus comprises: a status measurement unit that measures the status amount of a storage battery connected to an electric power system; a storage unit that stores the status amount data indicating the status amount measured by the status measurement unit and a time at which the status amount was measured by the status measurement unit; a transmission unit that transmits the status amount data stored in the storage unit; a reception unit that receives charging/discharging instruction data for instructing storage batteries to be charged or discharged; and a control unit that controls the charging/discharging amounts of the storage batteries on the basis of the charging/discharging instruction data.SELECTED DRAWING: Figure 3

Description

  The present invention relates to an information processing device, a control device for a power storage device, a power system, a control method, and a program.

With the liberalization of electric power, power storage devices have become widespread, and various operations are performed according to the purpose of use of the owner of the power storage device.
Patent Document 1 describes a technique for generating a command value for a power storage device based on a sharing rate according to a charge rate in order to operate a power storage device having different characteristics as a related technique.

Japanese Patent Laid-Open No. 2006-152718

By the way, with the liberalization of electric power, an increasing number of homes are installed with power storage devices for individuals.
In a power storage device installed in a home, even if it is operated based on a different usage purpose for each individual, that is, based on different actual loads, only a predetermined small number of operation modes are prepared in the power storage device. In many cases, the owner of the power storage device must select one of the few operation modes. In addition, in a power storage device installed in a home, the adjustable range of parameters that can be set is often narrow in each operation mode. Furthermore, the power storage device installed in the home is a power generation system (for example, a solar power generator: PV (Photovoltaics), a fuel cell: FC (fuel cell), etc.) that operates in cooperation with the output power of the power generation system. The state of use varies greatly around the world depending on the power consumption pattern of each power storage device owner.
In addition, with the liberalization of power, the power in the power system tends to be more unstable than before. Therefore, as with the power stabilization (frequency stabilization, power value stabilization) in the power system that was previously performed, the power used when charging and discharging the storage battery uniformly and periodically is used. Therefore, if the power in the power system is stabilized, the storage battery is more likely to deteriorate than before.

  Therefore, a technology that can suppress the deterioration of the power storage device and stabilize the power in the power system has been demanded.

  An object of the present invention is to provide an information processing device, a storage device control device, a power system, a control method, and a program that can solve the above-described problems.

  In order to achieve the above object, an aspect of the present invention includes an arithmetic unit that generates charge / discharge command data for instructing charging or discharging of a storage battery included in the power storage device based on state data from the power storage device. It is a processing device.

  In another aspect of the present invention, a state quantity measuring unit that measures a state quantity of a storage battery connected to an electric power system, state quantity data indicating the state quantity measured by the state quantity measuring unit, and the state quantity A storage unit that associates and stores the time at which the measurement unit measures the state quantity, a transmission unit that transmits state quantity data stored in the storage unit, and charging / discharging that instructs the storage battery to charge or discharge A control device for a power storage device comprising: a receiving unit that receives command data; and a control unit that controls a charge / discharge amount of the storage battery based on the charge / discharge command data.

  Another aspect of the present invention is an electric power system including the information processing device, the power storage device control device, and a storage battery included in the power storage device.

  Another aspect of the present invention is a control method including generating charge / discharge command data instructing charging or discharging of a storage battery included in the power storage device based on state data from the power storage device.

  In another aspect of the present invention, the state quantity of the storage battery connected to the power system is measured, the state quantity data indicating the measured state quantity is associated with the time when the state quantity is measured. Storing the stored state quantity data, receiving charge / discharge command data for instructing the storage battery to charge or discharge, and charging the storage battery based on the charge / discharge command data. Controlling the amount of discharge.

  In another aspect of the present invention, the state quantity of the storage battery connected to the power system is measured, the state quantity data indicating the measured state quantity is associated with the time when the state quantity is measured. Storing the stored state quantity data; generating charge / discharge command data for instructing the storage battery to charge or discharge based on the state data including the state quantity data; The control method includes receiving discharge command data and controlling a charge / discharge amount of the storage battery based on the charge / discharge command data.

  According to another aspect of the present invention, there is provided a program for causing a computer to generate charge / discharge command data instructing charging or discharging of a storage battery included in the power storage device based on state data from the power storage device. is there.

  According to another aspect of the present invention, a computer is configured to measure a state quantity of a storage battery connected to the power system, state quantity data indicating the measured state quantity, and a time when the state quantity is measured. Based on the charge / discharge command data, storing the associated data, transmitting the stored state quantity data, receiving charge / discharge command data instructing the storage battery to charge or discharge, and Controlling the charge / discharge amount of the storage battery.

  ADVANTAGE OF THE INVENTION According to this invention, deterioration of an electrical storage apparatus can be suppressed and the stabilization of the electric power in an electric power grid | system can be achieved.

It is a figure which shows the structure of the electric power system by one Embodiment of this invention. It is a figure which shows the structure of the electrical storage apparatus by one Embodiment of this invention. It is a figure which shows the structure of the information processing apparatus by one Embodiment of this invention. It is a figure for demonstrating the production | generation of the charging / discharging command value in one Embodiment of this invention. It is a figure which shows the processing flow of the electric power system by one Embodiment of this invention. It is a 1st figure for demonstrating the effect of the electric power system by one Embodiment of this invention. It is a figure which shows the minimum structure of the information processing apparatus by embodiment of this invention. It is a 2nd figure for demonstrating the effect of the electric power system by one Embodiment of this invention. It is a 3rd figure for demonstrating the effect of the electric power system by one Embodiment of this invention. It is a 4th figure for demonstrating the effect of the electric power system by one Embodiment of this invention. It is a 5th figure for demonstrating the effect of the electric power system by one Embodiment of this invention. It is a 6th figure for demonstrating the effect of the electric power system by one Embodiment of this invention. It is a 7th figure for demonstrating the effect of the electric power system by one Embodiment of this invention. It is an 8th figure for demonstrating the effect of the electric power system by one Embodiment of this invention.

<Embodiment>
Hereinafter, embodiments will be described in detail with reference to the drawings.
(Power system configuration)
The configuration of the power system 1 according to an embodiment of the present invention will be described.
As shown in FIG. 1, the power system 1 according to an embodiment of the present invention includes power storage devices 10 a, 10 b, 10 c, an information processing device 20, and a communication network 30.
The power storage devices 10a, 10b, and 10c are collectively referred to as the power storage device 10.

(Configuration of power storage device)
Each of the power storage devices 10 groups power storage devices 10 that are used under equivalent conditions to be described later, and a charge / discharge command value (charge / discharge command data for controlling charge / discharge of the storage battery according to the characteristics of each group. ) Is generated. And each of the electrical storage apparatus 10 uses the generated charging / discharging command value under the conditions with little deterioration of an own apparatus, and is charging / discharging of a storage battery so that the frequency fluctuation of the electric power accompanying the load fluctuation in an electric power grid | system may be suppressed. Control. Each of the power storage devices 10 is thus a device that suppresses power frequency fluctuations accompanying load fluctuations in the power system and suppresses deterioration of the own device.

  As shown in FIG. 2, each of the power storage devices 10 includes a storage battery 101, a measurement unit 102 (state quantity measurement unit, charge / discharge measurement unit), a storage unit 103, a transmission unit 104, a reception unit 105, and a control unit. Unit 106 and power conversion unit 107.

The storage battery 101 is a secondary battery that can charge and discharge the power system via the power conversion unit 107.
In addition, the storage battery 101 may be one in which a plurality of battery cells are connected in series, in parallel, and in series or parallel, or a combination of a plurality.

The measuring unit 102 measures the state quantity of the storage battery 101. Here, the state quantity of the storage battery 101 means the voltage output by the storage battery 101, the current output by the storage battery 101, the SOC (State Of Charge) of the storage battery 101, the temperature of the storage battery 101, the integrated value of the current output by the storage battery 101, These are the total amount of charge / discharge power charged / discharged by the storage battery 101, the remaining capacity of the storage battery 101 (SOH: State of Health), the usage period of the storage battery 101 (period from the start of use to the present), and the like.
Note that the measurement unit 102 may measure any one of these state quantities. The measurement unit 102 may measure a plurality of these state quantities.
Further, the timing at which the measurement unit 102 measures the state quantity of the storage battery 101 may be a predetermined timing set in advance (for example, timing at every certain period).
The measurement unit 102 writes the measured state quantity of the storage battery 101 in the storage unit 103. Here, data indicating the state quantity of the storage battery 101 measured by the measurement unit 102 is referred to as state quantity data.

The storage unit 103 stores state quantity data and measurement time in association with each other. Here, the measurement time is the time measured by the measurement unit 102.
In addition, the storage unit 103 stores installation area information and device specification information of the power storage device 10 including the self storage unit 103. Here, the installation area information is information indicating an installation area of the power storage device 10 including the self-storage unit 103. The device specification information is information indicating charge / discharge performance such as the total capacity (kWh) and charge / discharge power (kW) of the power storage device 10.

  The transmission unit 104 transmits measurement data to the information processing apparatus 20 via the communication network 30. Here, the state data is information including state quantity data, installation area information, and device specification information.

  The receiving unit 105 receives a charge / discharge command value from the information processing apparatus 20. Here, the charge / discharge command value is a command value for controlling charge / discharge of the power storage device 10.

The control unit 106 controls the charge / discharge amount of the storage battery 101 by controlling the power conversion unit 107 based on the charge / discharge command value received by the reception unit 105.
Further, the control unit 106 controls transmission of the transmission unit 104 and reception of the reception unit 105.
The power conversion unit 107 is connected to the power system, the storage battery 101, and the control unit 106. The power conversion unit 107 converts AC power received from the power system into DC power based on control by the control unit 106. Further, the power conversion unit 107 converts DC power received from the storage battery 101 into AC power based on the control by the control unit 106.

Note that, when the power storage device 10 is realized by hardware including a BMU (Battery Management Unit) and a system controller, the measurement unit 102 included in the BMU measures the state quantity of the storage battery 101. Further, when the power storage device 10 is realized by hardware including a BMU and a system controller, the storage unit 103 stores measurement amount data.
Further, in the situation where the transmission unit 104 is synchronized with the BMU, the state amount data stored in the storage unit 103 is read and acquired as it is, and the state amount data is processed (for example, the state amount data is selected, or In some cases, the state quantity data is averaged). Therefore, the transmission unit 104 acquires the state quantity data at a timing according to each case. It goes without saying that the transmission unit 104 may change the timing for acquiring the state quantity data due to other factors. The same applies to another embodiment of the present invention.

(Configuration of information processing device)
The information processing device 20 is a device that generates a charge / discharge command value according to an offset value with respect to a reference value described later, and transmits the generated charge / discharge command value to the power storage device 10 via a communication network.
As illustrated in FIG. 3, the information processing apparatus 20 includes a power system measurement unit 201 and a calculation unit 202.

The power system measurement unit 201 includes a frequency measurement unit 2011 and a power measurement unit 2012.
The frequency measurement unit 2011 measures the power frequency (at least one of the voltage frequency and the current frequency) in the power system.
The power measurement unit 2012 measures the magnitude of power in the power system.
The power system measurement unit 201 transmits the measured power frequency in the power system and the measured power level in the power system to the calculation unit 202.

The calculation unit 202 includes an offset generation unit 2021, a state acquisition unit 2022, a classification unit 2023, and a command value generation unit 2024.
The offset generation unit 2021 acquires a reference value for the frequency of power in the power system and a reference value for the magnitude of power in the power system.
Specifically, the offset generation unit 2021 reads the reference value of the power frequency in the power system stored in the storage unit 103 and the reference value of the power level in the power system. Further, the offset generation unit 2021 may be one in which a reference value for the frequency of power in the power system and a reference value for the magnitude of power in the power system are written in advance and hold these reference values.

  The offset generation unit 2021 receives from the power system measurement unit 201 the frequency of power in the power system measured by the power system measurement unit 201 and the magnitude of power in the power system measured by the power system measurement unit 201.

The offset generation unit 2021 compares the acquired power frequency reference value in the power system with the power frequency in the power system received from the power system measurement unit 201.
And the offset production | generation part 2021 produces | generates the frequency offset value according to the comparison result. Here, the frequency offset value is based on the reference value of the power frequency in the power system acquired by the offset generation unit 2021, and the frequency of the power in the power system received by the offset generation unit 2021 from the power system measurement unit 201 is the frequency offset value. It is a value indicating how much difference there is from the reference.

The offset generation unit 2021 compares the reference value of the power level in the power system with the power level in the power system received from the power system measurement unit 201.
Then, the offset generation unit 2021 generates a power offset value corresponding to the comparison result. Here, the power offset value is based on the reference value of the power level in the power system acquired by the offset generation unit 2021, and the power level in the power system received by the offset generation unit 2021 from the power system measurement unit 201. Is a value indicating how much difference there is from the reference.

  The offset generation unit 2021 transmits the generated frequency offset value and the generated power offset value to the command value generation unit 2024.

The state acquisition unit 2022 acquires state data of each power storage device 10.
The state acquisition unit 2022 transmits the acquired state data to the classification unit 2023 and the command value generation unit 2024.

The classification unit 2023 receives state data from the state acquisition unit 2022.
Based on the received state data, classification unit 2023 classifies each of power storage devices 10 for each group used under similar conditions. Here, the same conditions are conditions under which the charge / discharge patterns indicating the charge / discharge of the power storage device 10 are substantially the same, and the manner of deterioration of the power storage device 10 is substantially the same.
Specifically, the classification unit 2023 performs classification based on the remaining capacity, usage period, installation area information, and the like for each power storage device 10.
For example, the classification unit 2023 sets a remaining capacity threshold value for determining whether the remaining capacity is large or small. If classifying unit 2023 determines that the actual remaining capacity of power storage device 10 is equal to or greater than the remaining capacity threshold, it classifies power storage device 10 into a group with a large remaining capacity. Further, when determining that the actual remaining capacity of the power storage device 10 is less than the remaining capacity threshold value, the classification unit 2023 classifies the power storage device 10 into a group having a small remaining capacity.
For example, the classification unit 2023 sets a use period threshold value for determining whether the use period is long or short. Then, when determining that the actual use period of power storage device 10 is equal to or greater than the use period threshold value, classification unit 2023 classifies power storage device 10 into a group having a long use period. Further, when determining that the actual usage period of the power storage device 10 is less than the usage period threshold value, the classification unit 2023 classifies the power storage device 10 into a group having a short usage period.
For example, the classification unit 2023 divides the entire area where the power storage device 10 is installed into a plurality of areas. Classification unit 2023 regards each of the plurality of regions as one group, and classifies power storage device 10 into a group for each region. Then, classification unit 2023 classifies all of power storage devices 10 into each of the groups indicated by the combination of classifications.
In the above example, when it is assumed that the entire area where the power storage device 10 is installed is divided into two areas A and B, the classification unit 2023 combines the classifications (the remaining capacity is large and the use period is long). , Region A), (large remaining capacity, long use period, region B), (large remaining capacity, short use period, region A), (large remaining capacity, short use period, region B), (Remaining capacity is low, use period is long, area A), (Remaining capacity is low, use period is long, area B), (Remaining capacity is low, use period is short, area A), (Remaining capacity is low The area of use is classified into 8 types in the region B).
The classification unit 2023 classifies the power storage devices 10 used under the same conditions into one group, so that the charge / discharge patterns indicating the charge / discharge of the power storage devices 10 in each group are substantially the same, and the deterioration of the power storage devices 10 Can be regarded as almost the same.

  The classification unit 2023 transmits the classification result information to the command value generation unit 2024. Here, the classification result information is information including information (for example, an identifier of each power storage device 10) indicating the power storage device 10 for each group classified by the classification unit 2023.

The command value generation unit 2024 receives the frequency offset value and the power offset value from the offset generation unit 2021.
The command value generation unit 2024 receives state data from the state acquisition unit 2022.
The command value generation unit 2024 receives the classification result information from the classification unit 2023.

Based on the received frequency offset value, the received power offset value, and the received state data, the command value generation unit 2024 has a charge / discharge command value corresponding to the condition of the group for each group indicated by the classification result information. Then, a charge / discharge command value that cancels the frequency offset value and the power offset value is generated for each power storage device 10.
Specifically, as shown in FIG. 4, the command value generation unit 2024 generates a charge / discharge command value that instructs the storage battery 101 to discharge when the frequency of power in the power system decreases. Moreover, the command value generation unit 2024 generates a charge / discharge command value that instructs the storage battery 101 to charge when the frequency of power in the power system increases.

Note that, when the condition of the power storage device 10 is a condition in which the deterioration progresses quickly, the charge / discharge command value generated by the command value generation unit 2024 includes the condition of the power storage device 10 from the condition in which the deterioration progresses quickly to the progress of the deterioration. A command value including a command to change to a slow condition is included.
For example, when the condition of the power storage device 10 is a condition in which deterioration progresses quickly (for example, the SOC of the storage battery 101 is 100% and 0%), and the frequency of power in the power system decreases, the command value generation unit 2024 The condition of the device 10 is changed to a condition where the progress of deterioration is slow (for example, the SOC of the storage battery 101 is 50%), and a charge / discharge command value that instructs the storage battery 101 to discharge is generated.
In addition, for example, when the condition of the power storage device 10 is a condition in which deterioration progresses quickly and the frequency of power in the power system increases, the command value generation unit 2024 changes the condition of the power storage device 10 to a condition in which deterioration progresses slowly. The charge / discharge command value which changes and instruct | indicates charge with respect to the storage battery 101 is produced | generated.

Moreover, the command value generation unit 2024 may generate a charge / discharge command value that allocates a small charge / discharge amount to the power storage device 10 with a small remaining capacity.
In addition, command value generation unit 2024 generates a charge / discharge command value for assigning a large amount of charge / discharge to power storage device 10 having a short use period and a large remaining capacity.
Moreover, the command value generation unit 2024 generates a charge / discharge command value to which a charge / discharge amount is assigned according to an annual temperature fluctuation in the area where the power storage device 10 is installed. Specifically, the command value generation unit 2024 generates a charge / discharge command value that maximizes the charge / discharge amount in a temperature range where the progress of deterioration is small (for example, normal temperature 20 ° C. to 25 ° C.). In addition, the command value generation unit 2024 generates a charge / discharge command value for reducing the charge / discharge amount in a temperature range in which the progress of deterioration is large (for example, a temperature range higher or lower than normal temperature).

By doing so, the command value generation unit 2024 can suppress power frequency fluctuations in the power system and can suppress deterioration of the storage battery 101. As a result, the life of the storage battery 101 can be extended.
The power distribution company predicts the amount of power generation over a long period (one month, one year, etc.), and the frequency of power in the power system that is generated during one day when each power storage device 10 is charged and discharged. Suppress fluctuations.

Next, processing of the power system 1 according to an embodiment of the present invention will be described.
Here, the processing flow of the power system 1 shown in FIG. 5 will be described.
Note that in the description of the processing of the power system 1 according to the embodiment of the present invention, only one power storage device 10 may be described for convenience even when the plurality of power storage devices 10 perform the same processing. .

  Each of the transmission units 104 transmits state data regarding the power storage device 10 including the own transmission unit 104 to the information processing device 20 via the communication network 30 (step S1).

  The state acquisition unit 2022 receives state data from each of the transmission units 104 (step S2).

The frequency measurement unit 2011 measures the power frequency (at least one of the voltage frequency and the current frequency) in the power system. The frequency measurement unit 2011 transmits the measured frequency of power in the power system to the calculation unit 202.
The power measurement unit 2012 measures the magnitude of power in the power system. The power measurement unit 2012 transmits the magnitude of the measured power in the power system to the calculation unit 202.
The offset generation unit 2021 receives the frequency of power in the power system from the frequency measurement unit 2011 (step S3).
The offset generation unit 2021 receives the magnitude of power in the power system from the power measurement unit 2012 (step S4).

The offset generation unit 2021 acquires a reference value of the power frequency in the power system (step S5).
In addition, the offset generation unit 2021 acquires a reference value for the magnitude of power in the power system (step S6).

The offset generation unit 2021 compares the acquired power frequency reference value in the power system with the power frequency in the power system received from the power system measurement unit 201.
And the offset production | generation part 2021 produces | generates the frequency offset value on the basis of the reference value of the frequency of the electric power in an electric power grid | system (step S7).

Further, the offset generation unit 2021 compares the acquired reference value of the power level in the power system with the power level in the power system received from the power system measurement unit 201.
And the offset production | generation part 2021 produces | generates the electric power offset value on the basis of the reference value of the magnitude | size of the electric power in an electric power grid | system (step S8).

  The offset generation unit 2021 transmits the generated frequency offset value and the generated power offset value to the command value generation unit 2024.

The state acquisition unit 2022 acquires state data of each power storage device 10.
The state acquisition unit 2022 transmits the acquired state data to the classification unit 2023 and the command value generation unit 2024.

The classification unit 2023 receives state data from the state acquisition unit 2022.
Classification unit 2023 classifies each of power storage devices 10 into a plurality of groups based on the received state data (step S9).
The classification unit 2023 transmits the classification result information to the command value generation unit 2024.

The command value generation unit 2024 receives the frequency offset value and the power offset value from the offset generation unit 2021.
The command value generation unit 2024 receives state data from the state acquisition unit 2022.
The command value generation unit 2024 receives the classification result information from the classification unit 2023.
Based on the received frequency offset value, the received power offset value, and the received state data, the command value generation unit 2024 performs a charge / discharge command corresponding to the condition of the group for each group indicated by the classification result information. A value is generated for each power storage device 10 (step S10).
Command value generation unit 2024 transmits the generated charge / discharge command value to each of power storage devices 10 (step S11).

Receiving unit 105 receives a charge / discharge command value for controlling charging / discharging of own power storage device 10 from command value generating unit 2024 (step S12).
The control unit 106 controls the charge / discharge amount of the storage battery 101 based on the charge / discharge command value received by the receiving unit 105 (step S13).

By the way, in general, the progress of deterioration of the storage battery 101 is related to conditions such as the temperature at which the storage battery 101 operates and whether the storage battery 101 is used in cooperation with a solar power generator or a fuel cell.
As shown in FIG. 6, generally, the progress of deterioration of the storage battery 101 used in a higher temperature state (for example, ambient temperature 40 ° C.) than a normal temperature state (for example, ambient temperature 25 ° C.) It tends to be faster than the progress of deterioration of the storage battery 101 used at −20 ° C.).
In addition, the storage battery 101 is used in cooperation with a solar power generator or a fuel cell, and is often charged in a time zone where the power price is low (for example, at night). In addition, the storage battery 101 may be charged in at least one of early morning and evening with the power of the fuel cell that can increase energy efficiency by effectively using the exhaust heat.
Moreover, the electric power generated by the solar power generator during the day may be consumed. If the power generated by the solar power generator exceeds the power consumed during the day, the surplus power can be sold. On the other hand, in general, the power storage device 10 is often purchased using a subsidy, and in this case, the power charged in the storage battery 101 cannot be sold. Therefore, when the electric power generated by the solar power generator exceeds the power consumed during the day, the power charged in the storage battery 101 used in cooperation with the solar power generator is hardly used during the day. Therefore, the storage battery 101 is maintained in a fully charged state. Then, the electric power stored in the storage battery 101 starts to be consumed after sunset when the amount of power generated by the solar power generator is reduced.
In addition, the amount of power generated by solar power generators varies greatly depending on the region. In Japan, sunshine hours on the Pacific side are relatively long, but winter hours on the Sea of Japan side are very short. Further, even during the day, the amount of power generation varies greatly depending on whether the weather is clear, cloudy, or rainy. Therefore, in the weather such as rain and fine weather, the storage battery 101 may be charged using the power generated by the solar power generator after the power of the own battery is used up. In this case, the storage battery 101 is charged and discharged twice a day. Therefore, even if the usage period is the same from the installation time of power storage device 10, the capacity deterioration greatly changes for each storage battery 101.
Therefore, as shown in FIG. 6, the storage battery 101 that operates in cooperation with the solar power generator is more deteriorated in storage in the fully charged state than the storage battery 101 that operates without cooperation with the solar power generator. It becomes easy to do.
In addition, regardless of whether or not it operates in conjunction with the solar power generator, as shown in FIG. 6, the progress of the deterioration of the storage battery 101 in which an abnormality is detected is the deterioration of the storage battery 101 in which no abnormality is detected. Faster than progress.
Further, when the storage battery 101 is always used as an emergency power source in a charged state of 20 to 30% of the total capacity, the deterioration of the storage battery 101 progresses more than when the storage battery 101 is always used up. It tends to be faster.
Therefore, when power storage device 10 detects a large deviation from the normal progress of deterioration, calculation unit 202 can determine that an abnormality has occurred in storage battery 101.

  As described above, the information processing device 20 determines which capacity degradation of the storage battery 101 used under the same condition is obtained by extracting on the cloud a correlation obtained by comparing the states of the storage battery 101 in which the deterioration progresses. How to proceed. Therefore, even if the storage battery 101 has no detailed measurement data of the storage battery 101 and has a different use period, the information processing apparatus 20 can estimate the future life. Further, in the information processing apparatus 20, the progress of the deterioration of the storage battery 101 used under the same condition is different from the tendency of the deterioration of the other storage batteries used under the same condition. When it is determined that there is a possibility that deterioration due to a cause different from normal deterioration with time is likely to have occurred. Therefore, the information processing apparatus 20 estimates the occurrence of an abnormality in the storage battery 101 by monitoring the deterioration of the plurality of power storage apparatuses 10 used under the same conditions on the cloud in the communication network 30, and replaces parts. By proceeding with the preparation, it is possible to eliminate the inconvenience that the power storage device 10 cannot be used when the user needs it.

The information processing apparatus 20 according to the embodiment of the present invention has been described above. The information processing apparatus 20 according to an embodiment of the present invention includes a calculation unit 202 that generates charge / discharge command data for instructing charging or discharging of the storage battery 101 included in the power storage device 10 based on state data from the power storage device 10. Prepare.
By doing so, it is possible to suppress deterioration of the storage battery 101 and to stabilize power in the power system. In general, the storage battery 101 for home use is often maintained in a high state of charge, and in particular, it is possible to reduce the amount of stored power by discharging and to extend the service life. Both owners of the power storage device 10 can enjoy the benefits.

Next, the information processing apparatus 20 having the minimum configuration according to the embodiment of the present invention will be described.
The minimum configuration information processing apparatus 20 according to an embodiment of the present invention includes a calculation unit 202 as shown in FIG. Based on the state data from power storage device 10, operation unit 202 generates charge / discharge command data that instructs storage battery 101 included in power storage device 10 to charge or discharge.

In the case where the power storage device 10 performs charging and discharging with respect to the power system and performs control for suppressing fluctuations in the frequency of power in the power system as shown in the embodiment of the present invention, the service is It is often provided by, for example, an electric power company or a service company entrusted by the electric power company that can acquire the entire information. When performing the service, the power company or a service company entrusted by the power company cooperates with charging / discharging of the power in order to secure power for suppressing the frequency fluctuation of the power accompanying the load fluctuation in the power system. An incentive may be provided for the owner of the power storage device 10.
Further, the device specification information of the power storage device 10 is registered and becomes clear when the owner of the power storage device 10 cooperates with the service.

  In the embodiment of the present invention, the power system 1 has been described by taking the case where the power system 1 includes three power storage devices 10 as an example. However, the power storage device 10 included in the power system 1 according to the embodiment of the present invention is not limited to three. The power system 1 according to the embodiment of the present invention may include any number of power storage devices 10 as long as it is a plurality.

  The communication network 30 according to an embodiment of the present invention may be any communication network as long as communication can be appropriately performed between the power storage devices 10a to 10c and the information processing device 20.

  Note that in one embodiment of the present invention, the power storage device 10 is configured so that the voltage difference between the single cells is increased as necessary (for example, when the value of the voltage difference (MAX−MIN) between the single cells is greater than or equal to a certain value). It is also possible to perform a cell balance operation to reduce the value. In addition, the power storage device 10 inputs / outputs as necessary (for example, when a device such as a power converter causes at least one of a current and a voltage greater than a specified value between the device and the storage battery 101). You may provide the switch which interrupts | blocks electric power.

In general, when the power demand fluctuates from time to time, that is, when frequency fluctuation of power occurs with the load in the power system that fluctuates from time to time, the load fluctuation width and response time as shown in FIG. Control according to is performed.
FIG. 9 shows the adjustment of the output of a generator (for example, a hydroelectric power generator or a thermal power generator owned by an electric power company) that generates main power out of the electric power in the electric power system, and the frequency fluctuation of the electric power in the electric power system is adjusted. An example of suppression is shown.
In the past, suppression of fluctuations in the frequency of power in such a power system is often performed by adjusting the amount of power generated by a generator that generates main power. However, due to the liberalization of electric power, the electric power system needs to accept unstable electric power generated using renewable energy. Therefore, in order to stabilize the frequency of power in the power system, it is necessary to increase the power adjustment range using more power. As a result, the cost for increasing the power adjustment range tends to increase.
On the other hand, the control that suppresses the frequency variation of the power in the power system performed by the power storage device 10 according to the embodiment of the present invention has a plurality of responsiveness better than changing the output of a large generator in about several minutes. Since the storage battery 101 is used, a great effect can be obtained particularly when absorbing (compensating) the influence of frequency fluctuations of several minutes to 20 minutes.
Moreover, since the existing household storage battery 101 or the storage battery 101 for businesses can be used as the power storage device 10 according to the embodiment of the present invention, the power in the power system is not accompanied by a large increase in cost. It is possible to secure electric power for suppressing the frequency fluctuations.

In general, the general power storage device 10 is charged by nighttime power in the power system and starts discharging at dawn.
Similarly to the general power storage device 10, the power storage device 10 according to the embodiment of the present invention may be charged by night power in the power system and start discharging at dawn. In that case, the power storage device 10 according to an embodiment of the present invention has an upper limit of charge of SOC 90% or less as shown in FIG. 10, for example, in order to secure power for suppressing frequency fluctuations of power in the power system. The lower limit of discharge is set to SOC 10% or more.

Further, when the general power storage device 10 is used alone at home, it is first consumed from the electric power in the storage battery 101. Therefore, the SOC of power storage device 10 is likely to reach the lower limit quickly. On the other hand, in a general power storage device 10 that operates in cooperation with a solar power generator or a fuel cell, the time during which the SOC is maintained at a high value becomes long, and therefore there is a high possibility that the progress of deterioration will be accelerated.
Therefore, when the power storage device 10 according to the embodiment of the present invention is used alone, the variation of the power frequency in the power system is suppressed in consideration of the general power storage device 10 as shown in FIG. Therefore, the charging amount is set so as to increase in the charging / discharging amount of the power. In addition, when the power storage device 10 according to an embodiment of the present invention is used in cooperation with a solar power generator or a fuel cell, out of the charge / discharge amount of power for suppressing frequency variation of power in the power system Set to increase the amount of discharge.
In this way, the SOC of the power storage device 10 according to an embodiment of the present invention that operates in cooperation with a solar power generator or a fuel cell can be quickly reduced, and the life of the power storage device 10 can be extended. it can. In order to provide a difference between the charging power and the discharging power of the power storage device 10, the power distribution company provides an incentive to the owner of the power storage device 10 that operates the power storage device 10 according to an embodiment of the present invention alone. It may be provided. Note that the setting to unbalance the charge amount and discharge amount of power to suppress frequency fluctuations of power in the power system is different between the total power amount during the charge period and the total power amount during the discharge period. It only has to occur and is not limited to the waveform shown in FIG.

  In addition, when the power storage device 10 according to an embodiment of the present invention repeatedly charges and discharges to suppress frequency fluctuations of power in the power system, the temperature of the storage battery 101 is continuously increased depending on the amount of power charged and discharged by the power storage device 10. May rise. In this case, for each storage battery 101 at a different temperature in each installation area, the temperature rise can be suppressed to a certain level by suppressing the peak value of the charge / discharge amount to a certain level or less.

  Further, depending on the material of the storage battery 101 according to an embodiment of the present invention, as shown in FIG. 12, there may be a case where an endothermic reaction (a decrease in temperature) is exhibited for a certain period from the start of charge / discharge (start of charge in FIG. 12). . Therefore, the power storage device 10 according to the embodiment of the present invention can suppress an increase in the temperature of the storage battery 101 by actively using a region showing an endothermic reaction.

Moreover, depending on the material of the storage battery 101 in one embodiment of the present invention, as shown in FIG. 13, there is a storage battery 101 whose storage life depends on the SOC value. Therefore, by keeping the SOC value of the storage battery 101 in a high region, it is possible to reduce the unbalance between the charge amount and the discharge amount of the power that suppresses the frequency fluctuation of the power in the power system.
Specifically, for each storage battery group with different usage conditions (for example, presence or absence of PV, presence or absence of remaining amount setting, difference in outside temperature (by region), outdoor or indoor, whether or not air conditioning is present Depending on each group, etc.), change the setting periodically or set the offset to change the difference in input / output power. More specifically, for example, with respect to the storage battery 101 in which the remaining amount is set (for example, used in an area where the SOC value is 20 to 80%), the storage battery stored near the lower limit value of the SOC. For the group of 101, the charge / discharge power for stabilizing the frequency of the system power is in an unbalanced state (setting to increase the charge power and decrease the discharge power compared to it, or decrease the charge power, One of the settings for increasing the discharge power compared to the other). Then, the setting is changed periodically (for example, daily, weekly, etc.). By doing this, each of the groups of the storage batteries 101 stays at a specific SOC value while maintaining the waveform of the charging / discharging power for stabilizing the frequency of the required system power so as not to be distorted as a whole. It is possible to equalize the time to be performed and to uniformize the deterioration of each of the storage batteries 101 (refer to the region indicated by the arrow A in FIG. 13). Further, for storage battery 101 stored near the upper limit value of SOC, the battery is moved to a region where the amount of deterioration near the upper limit value of SOC is minimized (discharge is given priority here) (reference symbol B in FIG. 13). After that, the waveform in the charge / discharge power for stabilizing the frequency of the system power for the group of storage batteries 101 is maintained so as not to be distorted so as to move in the vicinity of the minimum value. However, the waveform of the charge / discharge power of each storage battery 101 is unbalanced. By carrying out like this, degradation of the storage battery 101 in a group can be equalize | homogenized, satisfying the request | requirement from the consumer in an electric power grid | system. Further, for example, when there is a storage battery 101 whose deterioration is maximum at a specific SOC (20%), the deterioration is promoted as the time for staying in the SOC becomes longer. There are two such storage batteries 101, and there is a difference in the correction amount of the grid power handled by the two batteries (for example, one is only discharging to the power grid and the other is only charging from the power grid). When the value reaches 30% and 10%, charging / discharging is reversed. Then, although the average value of SOC is 20%, it responds to the request | requirement from an electric power grid | system, and deterioration is suppressed also as a storage battery. Moreover, in the case of the storage battery 101 which cooperates with PV, SOC may be set to a high value (for example, 80%). In this case, as described above, the setting is periodically changed, the offset is set, or the storage battery 101 that is set to a lower SOC than the SOC of the storage battery 101 linked with the PV is used. The high value SOC of the storage battery 101 that cooperates with is shifted to a low value. In addition, in the case of the storage battery 101 in a high temperature state, the discharge is preferentially performed to shift from a high temperature state in which deterioration is likely to proceed to a temperature state in which deterioration is difficult to proceed.

Note that there are various charge / discharge command values generated by the command value generation unit 2024 in one embodiment of the present invention. Therefore, the control signal generated based on the charge / discharge command data by the control unit 106 in order to suppress the frequency of the power in the power system has various waveforms according to the state quantity of the storage battery 101.
FIG. 14 is a diagram illustrating an example of a power waveform for suppressing the frequency of power in the power system. The power waveform for suppressing the frequency of power in the power system can be most easily realized by a combination of sine waves having different periods. However, there are cases where the charge / discharge power fluctuates greatly in a short time. In that case, the waveform of the power for suppressing the frequency fluctuation of the power in the power system is close to a square wave. When the power waveform for suppressing the frequency fluctuation of the power in the power system is close to a square wave, the storage battery 101 is required to be charged / discharged at a high rate (large current).
Therefore, the load of each power storage device 10 is reduced by assigning a current to be supplied to the power storage device 10 according to the size of the capacity, or by combining the outputs of the power storage devices 10 including a large number of small capacity storage batteries 101.
Further, for example, each power storage device 10 can be changed by periodically changing the load assignment to each storage battery 101 or changing the load assignment according to the charge / discharge state or temperature state in the normal use state. It is conceivable to reduce the load.
As described above, the power storage device 10 can extend the life of the storage battery 101 by changing the power for charging / discharging in response to a steep charge / discharge request over a long period of time. Can also extend the life of the power conversion unit 107 built in.

  Note that the processing order of the processing according to the embodiment of the present invention may be changed within a range in which appropriate processing is performed.

  Each of the storage units in the embodiment of the present invention may be provided anywhere as long as appropriate information is transmitted and received. Each of the storage units may exist in a range in which appropriate information is transmitted and received, and data may be distributed and stored.

  Although the embodiment of the present invention has been described, the power storage device 10, the information processing device 20, and other control devices described above may have a computer system therein. The process described above is stored in a computer-readable recording medium in the form of a program, and the above process is performed by the computer reading and executing this program. Here, the computer-readable recording medium means a magnetic disk, a magneto-optical disk, a CD-ROM, a DVD-ROM, a semiconductor memory, or the like. Alternatively, the computer program may be distributed to the computer via a communication line, and the computer that has received the distribution may execute the program.

  The program may realize part of the functions described above. Further, the program may be a so-called difference file (difference program) that can realize the above-described functions in combination with a program already recorded in the computer system.

  Although several embodiments of the present invention have been described, these embodiments are examples and do not limit the scope of the invention. These embodiments may be added, variously omitted, replaced, and changed without departing from the gist of the invention.

  In addition, although a part or all of said embodiment can be described also as the following additional remarks, it is not restricted to the following.

(Additional remark 1) Based on the state data from an electrical storage apparatus, the calculating part which produces | generates the charge / discharge command data which instruct | indicates charge or discharge to the storage battery with which the said electrical storage apparatus is provided,
An information processing apparatus comprising:

(Appendix 2) The calculation unit
Based on the state data, predicting future deterioration in the storage battery, and determining whether a future abnormality occurs,
The information processing apparatus according to attachment 1.

(Supplementary note 3)
Based on the state data, group the power storage devices, and generate the charge / discharge command data according to each group grouped,
The information processing apparatus according to appendix 1 or appendix 2.

(Supplementary Note 4) A state quantity measuring unit that measures a state quantity of a storage battery connected to the power system,
A storage unit for storing state quantity data indicating the state quantity measured by the state quantity measurement unit and a time when the state quantity measurement unit measures the state quantity;
A transmission unit for transmitting state quantity data stored in the storage unit;
A receiving unit that receives charge / discharge command data that instructs charging or discharging of the storage battery;
Based on the charge / discharge command data, a control unit for controlling the charge / discharge amount of the storage battery,
A control device for a power storage device.

(Additional remark 5) The charging / discharging measurement part which measures the actual charging / discharging amount corresponding to the said charging / discharging command data,
The control apparatus for a power storage device according to claim 4, further comprising:

(Appendix 6) The control unit
Changing the charge / discharge amount of the storage battery for each cycle;
The storage device control apparatus according to appendix 4 or appendix 5.

(Appendix 7) The control unit
Based on the charge / discharge command data, a control signal having a waveform corresponding to the state quantity of the storage battery is generated, and the charge / discharge amount of the storage battery is controlled using the generated control signal.
The control apparatus for a power storage device according to any one of appendix 4 to appendix 6.

(Appendix 8) The information processing apparatus according to any one of Appendix 1 to Appendix 3,
The control device for the power storage device according to any one of appendix 4 to appendix 7,
A storage battery provided in the power storage device;
A power system comprising:

(Additional remark 9) Based on the state data from an electrical storage apparatus, producing | generating the charge / discharge command data which instruct | indicates charge or discharge to the storage battery with which the said electrical storage apparatus is provided,
Control method.

(Supplementary Note 10) Measuring the state quantity of the storage battery connected to the power system;
Storing the state quantity data indicating the measured state quantity in association with the time when the state quantity was measured;
Sending stored state quantity data;
Receiving charge / discharge command data instructing the storage battery to charge or discharge;
Based on the charge / discharge command data, controlling the charge / discharge amount of the storage battery;
Control method.

(Appendix 11) Measuring the state quantity of a storage battery connected to the power system;
Storing the state quantity data indicating the measured state quantity in association with the time when the state quantity was measured;
Sending stored state quantity data;
Generating charge / discharge command data instructing the storage battery to charge or discharge based on the state data including the state quantity data;
Receiving the charge / discharge command data;
Based on the charge / discharge command data, controlling the charge / discharge amount of the storage battery;
Control method.

(Supplementary note 12)
Generating charge / discharge command data instructing charging or discharging of a storage battery included in the power storage device based on state data from the power storage device;
A program that executes

(Supplementary note 13)
Measuring the state quantity of the storage battery connected to the power system;
Storing the state quantity data indicating the measured state quantity in association with the time when the state quantity was measured;
Sending stored state quantity data;
Receiving charge / discharge command data instructing the storage battery to charge or discharge;
Based on the charge / discharge command data, controlling the charge / discharge amount of the storage battery;
A program that executes

(Supplementary note 14)
Measuring the state quantity of the storage battery connected to the power system;
Storing the state quantity data indicating the measured state quantity in association with the time when the state quantity was measured;
Sending stored state quantity data;
Generating charge / discharge command data instructing the storage battery to charge or discharge based on the state data including the state quantity data;
Receiving the charge / discharge command data;
Based on the charge / discharge command data, controlling the charge / discharge amount of the storage battery;
A program that executes

DESCRIPTION OF SYMBOLS 1 ... Electric power system 10, 10a, 10b, 10c ... Power storage device 20 ... Information processing device 30 ... Communication network 101 ... Storage battery 102 ... Measurement part 103 ... Storage part 104- ..Transmission unit 105 ... Reception unit 106 ... Control unit 107 ... Power conversion unit 201 ... Power system measurement unit 202 ... Calculation unit 2011 ... Frequency measurement unit 2012 ... Power measurement Unit 2021 ... offset generation unit 2022 ... state acquisition unit 2023 ... classification unit 2024 ... command value generation unit

Claims (10)

An arithmetic unit that generates charge / discharge command data for instructing charging or discharging of a storage battery included in the power storage device, based on state data from the power storage device,
An information processing apparatus comprising: The computing unit is
Based on the state data, predicting future deterioration in the storage battery, and determining whether a future abnormality occurs,
The information processing apparatus according to claim 1. The computing unit is
Based on the state data, group the power storage devices, and generate the charge / discharge command data according to each group grouped,
The information processing apparatus according to claim 1 or 2. A state quantity measuring unit for measuring a state quantity of the storage battery connected to the power system;
A storage unit for storing state quantity data indicating the state quantity measured by the state quantity measurement unit and a time when the state quantity measurement unit measures the state quantity;
A transmission unit for transmitting state quantity data stored in the storage unit;
A receiving unit that receives charge / discharge command data that instructs charging or discharging of the storage battery;
Based on the charge / discharge command data, a control unit for controlling the charge / discharge amount of the storage battery,
A control device for a power storage device. An information processing apparatus according to any one of claims 1 to 3,
The power storage device control device according to claim 4,
A storage battery provided in the power storage device;
A power system comprising: Generating charge / discharge command data instructing charging or discharging of a storage battery included in the power storage device based on state data from the power storage device;
Control method. Measuring the state quantity of the storage battery connected to the power system;
Storing the state quantity data indicating the measured state quantity in association with the time when the state quantity was measured;
Sending stored state quantity data;
Receiving charge / discharge command data instructing the storage battery to charge or discharge;
Based on the charge / discharge command data, controlling the charge / discharge amount of the storage battery;
Control method. Measuring the state quantity of the storage battery connected to the power system;
Storing the state quantity data indicating the measured state quantity in association with the time when the state quantity was measured;
Sending stored state quantity data;
Generating charge / discharge command data instructing the storage battery to charge or discharge based on the state data including the state quantity data;
Receiving the charge / discharge command data;
Based on the charge / discharge command data, controlling the charge / discharge amount of the storage battery;
Control method. On the computer,
Generating charge / discharge command data instructing charging or discharging of a storage battery included in the power storage device based on state data from the power storage device;
A program that executes On the computer,
Measuring the state quantity of the storage battery connected to the power system;
Storing the state quantity data indicating the measured state quantity in association with the time when the state quantity was measured;
Sending stored state quantity data;
Receiving charge / discharge command data instructing the storage battery to charge or discharge;
Based on the charge / discharge command data, controlling the charge / discharge amount of the storage battery;
A program that executes

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