JP2016185044A - Power storage battery managing device, control device, power storage battery module and power storage battery managing method - Google Patents

Abstract

A storage battery management apparatus capable of reducing the setting work of information related to control such as charging is provided. A storage battery management device includes a characteristic information acquisition unit that acquires characteristic information from a storage battery module, and a power supply control device that controls at least one of charging and discharging of the storage battery module. And a notification unit 34 for notifying the control condition. Thereby, the storage battery management device 30 can perform control such as charging under appropriate conditions even when the operator forgets the information setting operation. [Selection] Figure 1

Description

  The present invention generally relates to a storage battery management device, a control device, a storage battery module, and a storage battery management method, and more particularly to a storage battery management device, a control device, a storage battery module, and a storage battery management method for managing charging or discharging of the storage battery module. .

  Conventionally, when a lithium ion secondary battery (hereinafter referred to as a storage battery) is charged, there is a charging circuit that controls a charging voltage in accordance with the temperature of the battery (see Patent Document 1).

  The charging circuit described in Patent Document 1 includes a power supply circuit and a control circuit. The control circuit includes a storage unit that stores a voltage (threshold voltage) corresponding to the temperature of the storage battery, and acquires the threshold voltage corresponding to the temperature detected by the temperature detection circuit from the storage unit. The power supply circuit controls charging of the storage battery based on the threshold voltage acquired by the control circuit.

JP 2009-22078 A

  Since the performance of the storage battery module decreases due to repeated charging and discharging, it is necessary to replace the storage battery module with a new storage battery module at a certain point in time. In the storage battery module before replacement and the storage battery module after replacement, the threshold voltage for the storage battery module before replacement may be different from the threshold voltage for the storage battery module after replacement.

  As described above, in the charging circuit of Patent Document 1, the control circuit stores the threshold voltage in advance. Therefore, in order to appropriately charge the storage battery module after replacement, it is necessary to change the setting of the threshold voltage stored in the control circuit to the threshold voltage for the storage battery module after replacement. At this time, the operator may forget to reset the threshold voltage.

  Therefore, the present invention has been made in view of the above-mentioned reasons, and the purpose thereof is a storage battery management device capable of controlling charging and the like under appropriate conditions even when the operator forgets to set information. It is providing a control apparatus, a storage battery module, and a storage battery management method.

  A storage battery management device according to one aspect of the present invention is based on the characteristic information in a characteristic information acquisition unit that acquires characteristic information from the storage battery module and a power supply control device that controls at least one of charging and discharging of the storage battery module. A notification unit for notifying the control condition.

  In addition, a control device according to one aspect of the present invention includes the above-described storage battery management device and the power supply control device. When the power supply control device receives the control condition from the storage battery management device, the control condition is satisfied. Based on this, the storage battery module is controlled.

  The storage battery module according to one aspect of the present invention delivers the characteristic information to a storage battery, a storage unit that stores characteristic information for at least one of charging and discharging, and a storage battery management device that manages the characteristic information. And an output unit.

  Further, the storage battery management method according to one aspect of the present invention provides the characteristic information acquisition process for acquiring characteristic information from the storage battery module and the power supply control device that performs control on at least one of charging and discharging of the storage battery module. Notification processing for notifying control conditions based on the above.

  According to the storage battery management device, the control device, the storage battery module, and the storage battery management method described above, it is possible to control charging and the like under appropriate conditions even when the operator forgets the information setting operation.

It is a figure explaining the structure of the electrical storage system in Embodiment 1. FIG. 3 is a flowchart illustrating the operation of the storage battery management device according to the first embodiment. It is a figure explaining the structure of the electrical storage system in the modification 1 of Embodiment 1. FIG. It is a flowchart explaining the operation | movement which the storage battery management apparatus in the modification 1 of Embodiment 1 determines the minimum charging current value as control conditions. It is a flowchart explaining the operation | movement which the storage battery management apparatus in the modification 1 of Embodiment 1 determines the minimum discharge current value as control conditions. It is a figure explaining the structure of the electrical storage system in Embodiment 2. FIG. It is a figure explaining the structure of the storage battery module in Embodiment 2. FIG. It is a flowchart explaining operation | movement of the storage battery module in Embodiment 2. FIG. It is a flowchart explaining operation | movement of the storage battery management apparatus in Embodiment 2. FIG. It is a figure explaining the structure of the electrical storage system in the modification of Embodiment 2. FIG. It is a flowchart explaining the operation | movement in which the storage battery module in the modification of Embodiment 2 determines a charging current value as characteristic information. It is a flowchart explaining the operation | movement in which the storage battery module in the modification of Embodiment 2 determines a discharge current value as characteristic information.

1 Embodiment 1
Hereinafter, the power storage system 1 in the present embodiment will be described.

  As shown in FIG. 1, the power storage system 1 in this embodiment includes a storage battery system 10 including a plurality of storage battery modules 11 and a control device 20. The power storage system 1 is a system in which the control device 20 controls at least one of charging and discharging of each of the plurality of storage battery modules 11 using the characteristic information stored in each of the plurality of storage battery modules.

  The storage battery module 11 delivers characteristic information representing the characteristics of the storage battery module 11 to the control device 20. In the present embodiment, the characteristic information is information regarding at least one of charging and discharging.

  The control device 20 controls at least one of charging and discharging of each storage battery module 11. When the control device 20 acquires the characteristic information from each of the plurality of storage battery modules 11, the control device 20 selects a control condition based on the acquired characteristic information. The control device 20 controls at least one of charging and discharging of the storage battery module 11 based on the selected control condition. Hereinafter, a case where the control condition is a condition related to charging will be described.

(Storage battery module 11)
As shown in FIG. 1, each of the plurality of storage battery modules 11 includes a storage battery 12, a temperature sensor 13, a storage unit 14, and an output unit 15. In this embodiment, the some storage battery module 11 is the same kind and the same performance on specification.

  The storage battery 12 is, for example, a lithium ion battery.

  The plurality of temperature sensors 13 measure the battery temperature (environment information) of the storage battery 12 and pass the result to the control device 20.

  The storage unit 14 stores a fully charged voltage value when the battery temperature belongs to the first temperature range and a fully charged voltage value when the battery temperature belongs to the second temperature range. Here, the first temperature range is a range in which the battery temperature is higher than a predetermined threshold value, and is a range in which the performance of the storage battery module 11 is exhibited as usual without being limited by specifications. Hereinafter, a fully charged voltage value in the first temperature range is referred to as a normal voltage value. The second temperature range is a range in which the temperature is equal to or lower than a predetermined threshold, and is a range where the performance of the storage battery module 11 is exhibited in a state where the specifications are limited. Hereinafter, a fully charged voltage value in the second temperature range is referred to as a limit voltage value. Specifically, the storage unit 14 stores the first voltage range in association with the normal voltage value and the second temperature range in association with the limit voltage value. In the present embodiment, the limit voltage value is a value smaller than the normal voltage value. As a result, when the battery temperature is equal to or lower than the predetermined threshold value, the amount of electric power charged is smaller than that in normal charging (when the battery temperature is higher than the predetermined threshold value), thereby extending the life. Can do. Moreover, as above-mentioned, the some storage battery module 11 is the same kind and the same performance on a specification. Therefore, the normal voltage value stored in each storage unit 14 of the plurality of storage battery modules 11 is the same for each storage battery module 11, and the limit voltage value is also the same for each storage battery module 11.

  The output unit 15 delivers the characteristic information to the control device 20. In the present embodiment, the characteristic information is information including a first full charge condition that is a set of a normal voltage value and a first temperature range, and a second full charge condition that is a set of a limit voltage value and a second temperature range. is there.

  In addition, the some storage battery module 11 is electrically connected by connecting each storage battery 12 in series.

(Control device 20)
The control device 20 is a power conditioner, and includes a storage battery management device 30 and a power supply control device 40 as shown in FIG.

  The storage battery management device 30 is a device that manages characteristic information. In the present embodiment, the characteristic information is information related to at least one of charging and discharging of the storage battery module 11. The storage battery management device 30 acquires characteristic information from the plurality of storage battery modules 11, and selects a control condition suitable for the plurality of storage battery modules 11 using each characteristic information. As shown in FIG. 1, the storage battery management device 30 includes a characteristic information acquisition unit 31, a discrimination information acquisition unit 32, a processing unit 33, and a notification unit 34. The storage battery management device 30 has a processor or a computer-readable memory, and each function of the storage battery management device 30 is realized by the processor executing a program stored in the memory. This program is provided through a telecommunication line such as the Internet, or is provided by a computer-readable recording medium.

  The characteristic information acquisition unit 31 acquires characteristic information including each of the first full charge condition and the second full charge condition from each storage battery module 11 at the start of charging.

  The discrimination information acquisition unit 32 acquires discrimination information for selecting a control condition (in this embodiment, a condition for controlling charging) of each storage battery module 11 at the start of charging. Specifically, the discrimination information acquisition unit 32 acquires the battery temperature of each storage battery module 11 (storage battery 12) from each temperature sensor 13 as discrimination information.

  The processing unit 33 uses the characteristic information acquired by the characteristic information acquisition unit 31 to select a control condition suitable for the plurality of storage battery modules 11. Specifically, the processing unit 33 uses the determination information acquired by the determination information acquisition unit 32 to determine which of the first full charge condition and the second full charge condition for each of the plurality of storage battery modules 11. Select the full charge condition. The processing unit 33 selects a full charge condition including the lowest voltage value among the selected full charge conditions as a control condition.

  The notification unit 34 sets the control condition to the power control device 40 in order to cause the power control device to control each storage battery module 11 (storage battery 12) based on the voltage value included in the control condition selected by the processing unit 33. To notify.

  The power supply control device 40 is a device that charges each storage battery module 11 (storage battery 12) using the generated power of the solar battery 50. The power supply control device 40 controls at least one of charging and discharging for each storage battery module 11 (storage battery 12) based on the control condition notified from the storage battery management device 30. For example, the power supply control device 40 receives a control condition (full charge condition) from the storage battery management device 30. The power supply control device 40 charges each storage battery module 11 using the generated power of the solar battery 50 so that the voltage value at the time of full charge of each storage battery module 11 becomes a voltage value represented by the received full charge condition. I do. Specifically, the power supply control device 40 measures the voltage value of each storage battery module 11 when each storage battery module 11 is charged, and when the measured voltage value matches the voltage value represented by the full charge condition. Stop charging.

  In addition, the power supply control device 40 converts at least one power of the storage battery modules 11 and the solar battery 50 into alternating current, and supplies the power to a load 51 provided in the facility. The power supply control device 40 performs discharge control of each storage battery module 11 when supplying power to the load 51 using the power of each storage battery module 11.

  Note that the power supply control device 40 includes a processor and a memory, and each function of the power supply control device 40 is realized by the processor executing a program stored in the memory. This program is provided through a telecommunication line such as the Internet, or is provided by a computer-readable recording medium.

  Next, the operation in which the storage battery management device 30 determines the control conditions will be described with reference to the flowchart shown in FIG.

  The characteristic information acquisition unit 31 of the storage battery management device 30 acquires characteristic information from the plurality of storage battery modules 11 (step S5). Specifically, the characteristic information acquisition unit 31 acquires characteristic information including each of the first full charge condition and the second full charge condition from each storage battery module 11. The discrimination information acquisition unit 32 of the storage battery management device 30 acquires the battery temperatures (discrimination conditions) of the plurality of storage battery modules 11 (storage batteries 12) from the plurality of temperature sensors 13 (step S10).

  The processing unit 33 of the storage battery management device 30 uses the characteristic information acquired by the characteristic information acquisition unit 31 to perform a selection process for selecting a control condition suitable for the plurality of storage battery modules 11 (step S15). For example, the processing unit 33 uses the battery temperature acquired from the storage battery module among the first full charge condition and the second full charge condition included in the characteristic information acquired from the storage battery module 11 for each of the plurality of storage battery modules 11. Select the full charge condition according to the. Specifically, the processing unit 33 selects the first full charge condition when the battery temperature is higher than a predetermined threshold, and selects the second full charge condition when the battery temperature is equal to or lower than the predetermined threshold. . When each full charge condition is the first full charge condition, the processing unit 33 selects the first full charge condition as the control condition. When the second full charge condition is selected for at least one storage battery module 11 among the plurality of storage battery modules 11, the processing unit 33 selects the second full charge condition as a control condition.

  The notification unit 34 of the storage battery management device 30 notifies the power supply control device 40 of the control condition (full charge condition) selected by the processing unit 33 (step S20). The power supply control device 40 controls the voltage when each storage battery module 11 is fully charged based on the voltage value included in the control condition (full charge condition) notified by the notification unit 34.

  In this embodiment, although the storage battery system 10 was comprised with the some storage battery module 11, it is not limited to this. The storage battery system 10 may be configured by at least one storage battery module 11. For example, when the storage battery system 10 is configured by one storage battery module 11, the storage battery management device 30 acquires characteristic information from the one storage battery module 11, and uses the acquired characteristic information to store the storage battery module 11. Select suitable control conditions. When the characteristic information includes the first full charge condition and the second full charge condition, the storage battery management device 30 acquires the first full charge condition acquired from the one storage battery module 11 when the battery temperature is higher than a predetermined threshold. Is set as a control condition. When the battery temperature is equal to or lower than a predetermined threshold, the storage battery management device 30 uses the voltage value included in the second full charge condition acquired from the one storage battery module 11 as a control condition.

  Moreover, although the storage battery management apparatus 30 of this embodiment acquired characteristic information and discrimination | determination information at the time of charge start, it is not limited to this. The storage battery management device 30 may acquire the characteristic information and the discrimination information at a predetermined cycle (for example, every 3 hours). In addition, this numerical value is an example, Comprising: It is not the meaning limited to these numerical values.

  Although the memory | storage part 14 of the storage battery module 11 of this embodiment memorize | stores two types of voltage values (a normal voltage value, a limit voltage value), it is not limited to this. The storage unit 14 of the storage battery module 11 may store a plurality of types of voltage values. A plurality of different temperature ranges are associated one-to-one with a plurality of different voltage values. The output unit 15 delivers to the storage battery management device 30 characteristic information including a voltage value and a plurality of sets that are in a temperature range associated with the voltage value. The storage battery management device 30 selects a voltage value corresponding to the battery temperature acquired by the determination information acquisition unit 32 from among the voltage values included in the characteristic information.

  Moreover, although the some storage battery module 11 was set as the same kind and the same performance on the specification, it is not limited to this. Different types and performances may be mixed in the plurality of storage battery modules 11. In this case, the normal voltage value and the limit voltage value are different for each of the plurality of types. When the processing unit 33 of the storage battery management device 30 selects the first full charge condition from each of the plurality of storage battery modules 11, the first full charge condition including the lowest voltage value among the selected first full charge conditions. Is selected as the control condition. When the processing unit 33 selects the second full charge condition for at least one of the storage battery modules 11, the processing unit 33 controls the second full charge condition including the lowest voltage value among the selected second full charge conditions. Select as a condition.

  Moreover, although each storage battery 12 shall be connected in series, parallel connection may be sufficient and the connection in which serial connection and parallel connection were mixed may be sufficient.

  In the present embodiment, the voltage value is used as the full charge condition, but the present invention is not limited to this. The charging rate (SOC: State of Charge) of the storage battery module 11 may be used as a full charge condition. For example, the storage unit 14 of the storage battery module 11 stores a set of a first temperature range and a charging rate “100%” and a set of a second temperature range and a charging rate “80%”. The output unit 15 delivers the characteristic information including these sets to the storage battery management device 30. When each battery temperature of the plurality of storage battery modules 11 belongs to the first temperature range, the storage battery management device 30 selects 100% as the charging rate. When the battery temperature of at least one storage battery module 11 belongs to the second temperature range, the processing unit 33 of the storage battery management device 30 selects 80% as the charging rate. At this time, each of the plurality of storage battery modules 11 includes a measurement circuit that measures the charging rate of the storage battery 12. The power supply control device 40 controls the charging of each storage battery module 11 so that the charging rate selected by the storage battery management device 30 is obtained based on the results measured by the respective measurement circuits of the plurality of storage battery modules 11.

  As described above, the storage battery management device 30 according to one aspect of the present invention includes the characteristic information acquisition unit 31 and the notification unit 34. The characteristic information acquisition unit 31 acquires characteristic information from the storage battery module 11. The notification unit 34 notifies the power supply control device 40 that controls at least one of charging and discharging of the storage battery module 11 of the control condition based on the characteristic information.

  According to this configuration, the storage battery management device 30 acquires characteristic information from the storage battery module 11 and notifies the power supply control device 40 of a control condition based on the characteristic information. Therefore, the storage battery management device 30 can control charging and the like under appropriate conditions (control conditions) even when the operator forgets the information setting operation.

  Here, there are a plurality of storage battery modules 11. The characteristic information acquisition unit 31 acquires characteristic information from each of the plurality of storage battery modules 11. The storage battery management device 30 preferably further includes a processing unit 33 that selects control conditions suitable for the plurality of storage battery modules 11 using each characteristic information acquired by the characteristic information acquisition unit 31.

  According to this configuration, the storage battery management device 30 can control charging and the like under appropriate conditions (control conditions) for the plurality of storage battery modules 11 even when the operator forgets the information setting operation. it can.

  Here, the characteristic information includes a plurality of full charge conditions related to determination of full charge. The storage battery management device 30 further includes a discrimination information acquisition unit 32 that acquires discrimination information for selecting one full charge condition from a plurality of full charge conditions. The processing unit 33 selects one full charge condition among the plurality of full charge conditions using the discrimination information for each of the plurality of storage battery modules 11. It is preferable that the process part 33 selects the full charge conditions which are suitable with respect to the some storage battery module 11 among each selected full charge conditions as control conditions.

  According to this configuration, the storage battery management device 30 can set the full charge condition relating to the determination of full charge that is suitable for the plurality of storage battery modules 11. The storage battery management device 30 can control charging for all of the plurality of storage battery modules 11 by selecting the strictest condition as the control condition among the full charge conditions selected using the determination condition. .

  Here, the discrimination information is operating environment information related to the operating environment of the storage battery module 11. Each of the plurality of full charge conditions is a voltage value at the time of full charge according to the operating environment of the storage battery module 11. The processing unit 33 selects one full charge condition among the plurality of full charge conditions using the operating environment information for each of the plurality of storage battery modules 11, and the lowest voltage value among the selected full charge conditions. It is preferable to select a full charge condition representing

  According to this configuration, the storage battery management device 30 can set a voltage value at the time of full charge suitable for the plurality of storage battery modules 11.

  Here, the operating environment information is the battery temperature of the storage battery module 11. The discrimination information acquisition unit 32 acquires the battery temperature for each of the plurality of storage battery modules 11. It is preferable that the process part 33 selects the full charge conditions according to the battery temperature of the said storage battery module 11 about each of the some storage battery module 11. FIG.

  According to this configuration, the storage battery management device 30 selects the full charge condition corresponding to the battery temperature for each storage battery module 11. Therefore, the storage battery management device 30 can select an optimum voltage value for each storage battery module when the battery temperature of each storage battery module 11 is acquired.

  Moreover, the control apparatus 20 which is 1 aspect of this invention is provided with the storage battery management apparatus 30 and the power supply control apparatus 40 which were mentioned above. When the power supply control device 40 receives the control condition from the storage battery management device 30, the power supply control device 40 controls the storage battery module 11 based on the control condition.

  According to this structure, the control apparatus 20 can reduce the setting operation | work of the information regarding control, such as charge.

  Moreover, the storage battery management method which is one aspect of the present invention includes characteristic information acquisition processing and notification processing. The characteristic information acquisition process acquires characteristic information from the storage battery module 11. The notification process notifies the power supply control device 40 that controls at least one of charging and discharging of the storage battery module 11 of the control condition based on the characteristic information.

  According to this storage battery management method, it is possible to reduce the setting work of information related to control such as charging.

2 Modification 1 of Embodiment 1
Here, at least one of the charging current value and the discharging current value is used as the control condition, not the full charge condition. Here, the charging current value is a value of a current that the power supply control device 40 inputs to each storage battery module 11 when each storage battery module 11 is charged. The discharge current value is a value of a current input from each storage battery module 11 when the power storage control module 40 discharges each storage battery module 11.

  Hereinafter, a description will be given centering on differences from the first embodiment. In this modification, the same components as those in the first embodiment are denoted by the same reference numerals, and description thereof will be omitted as appropriate.

  As shown in FIG. 3, the power storage system 1 of this modification includes a storage battery system 10 and a control device 20.

  As shown in FIG. 3, the storage battery system 10 includes a plurality of storage battery modules 11, and each storage battery module 11 includes a storage battery 12, a storage unit 14, and an output unit 15. The storage unit 14 has a maximum current value input during charging (maximum charging current value, hereinafter “first maximum charging current value”) and a maximum current value output during discharging (maximum discharging current value, hereinafter “ 1st maximum discharge current value "). The output unit 15 delivers the first maximum charging current value and the first maximum discharging current value stored in the storage unit 14 to the storage battery management device 30 as characteristic information. In addition, the some storage battery module 11 is electrically connected by connecting each storage battery 12 in series.

  As illustrated in FIG. 3, the control device 20 includes a storage battery management device 30 and a power supply control device 40. As shown in FIG. 3, the storage battery management device 30 includes a characteristic information acquisition unit 31, a processing unit 33, a notification unit 34, and a current value acquisition unit 35.

  The characteristic information acquisition unit 31 acquires a charging current value and a discharging current value as characteristic information from each storage battery module 11 when the control device 20 is activated.

  When the power supply control device 40 controls the charging of each storage battery module 11, the current value acquisition unit 35 is a maximum current value that can be output to each storage battery module 11 (maximum charging current value, hereinafter “second maximum charging”). Current value ") is acquired from the power supply control device 40 when the control device 20 is started. Further, the current value acquisition unit 35, when the power supply control device 40 controls the discharge of each storage battery module 11, the value of the maximum current that can be input from each storage battery module 11 (maximum discharge current value, hereinafter “second maximum discharge”). Current value ") is acquired from the power supply control device 40.

  The processing unit 33 selects a control condition suitable for the plurality of storage battery modules by using at least one of the first maximum charging current value and the first maximum discharging current value acquired by the characteristic information acquisition unit 31. For example, when the characteristic information acquisition unit 31 acquires the first maximum charging current value from each storage battery module 11, the processing unit 33 selects the minimum current value (charging limit value) among the acquired first maximum charging current values. To do. The processing unit 33 selects, as a control condition, a smaller current value (charging control current value) among the selected charging limit value and the maximum charging current value acquired by the current value acquiring unit 35. In addition, when the characteristic information acquisition unit 31 acquires the first maximum discharge current value from each storage battery module 11, the processing unit 33 selects the minimum current value (discharge limit value) among the acquired first maximum discharge current values. To do. The processing unit 33 selects, as a control condition, a smaller current value (discharge control current value) between the selected discharge limit value and the maximum discharge current value acquired by the current value acquisition unit 35.

  The notification unit 34 notifies the power supply control device 40 of the control condition (charge control current value or discharge control current value) selected by the processing unit 33.

  When the control condition is a charge control current value, the power supply control device 40 controls the charging of each storage battery module 11 (storage battery 12) based on the charge control current value. When the control condition is a discharge control current value, the power supply control device 40 controls the discharge of each storage battery module 11 (storage battery 12) based on the discharge control current value.

  Next, the operation | movement which the storage battery management apparatus 30 of this modification determines a control condition is demonstrated using the flowchart shown in FIG. 4, FIG.

  An operation in which the storage battery management device 30 according to this modification determines a charge control current value as a control condition will be described with reference to the flowchart shown in FIG.

  The characteristic information acquisition unit 31 acquires the first maximum charging current value from the plurality of storage battery modules 11 as characteristic information (step S50). The current value acquisition unit 35 acquires the second maximum charging current value from the power supply control device 40 (step S55).

  The processing unit 33 uses each characteristic information acquired by the characteristic information acquisition unit 31 to perform a selection process for selecting a control condition suitable for the plurality of storage battery modules 11 (step S60). Specifically, the processing unit 33 sets a smaller current value (charge control current value) between the minimum current value (charge limit value) of the first maximum charge current values and the second maximum charge current value. Select as a control condition.

  The notification unit 34 notifies the power supply control device 40 of the control condition (charge control current value) selected by the processing unit 33 (step S65). The power supply control device 40 controls the current input to each storage battery module 11 during charging based on the control condition (current value for charge control) notified by the notification unit 34.

  Next, an operation in which the storage battery management device 30 according to the present modification determines the discharge control current value as a control condition will be described with reference to the flowchart shown in FIG.

  The characteristic information acquisition unit 31 acquires the first maximum discharge current value from the plurality of storage battery modules 11 as characteristic information (step S100). The current value acquisition unit 35 acquires the second maximum discharge current value from the power supply control device 40 (step S105).

  The processing unit 33 uses each characteristic information acquired by the characteristic information acquisition unit 31 to perform a selection process for selecting a control condition suitable for the plurality of storage battery modules 11 (step S110). Specifically, the processing unit 33 sets a smaller current value (discharge control current value) between the minimum current value (discharge limit value) and the second maximum discharge current value among the first maximum discharge current values. Select as a control condition.

  The notification unit 34 notifies the power supply control device 40 of the control condition (discharge control current value) selected by the processing unit 33 (step S115). The power supply control device 40 controls the current output by each storage battery module 11 during discharging based on the control condition (discharge control current value) notified by the notification unit 34.

  In addition, although the storage battery management apparatus 30 of this modification is a structure which is not provided with the discrimination | determination information acquisition part 32 mentioned above, it is not limited to this. The storage battery management device 30 of this modification may include a discrimination information acquisition unit 32, and the storage battery module 11 may include the temperature sensor 13. In this case, the control device 20 performs both charge control based on the full charge condition and charge / discharge control based on the current value related to charge / discharge. Since the control of charging based on the full charge condition has already been described, description thereof is omitted here.

  Moreover, although the storage battery system 10 of this modified example was comprised with the some storage battery module 11, it is not limited to this. The storage battery system 10 may be configured by at least one storage battery module 11. For example, when the storage battery system 10 is configured by one storage battery module 11, the storage battery management device 30 acquires characteristic information from the one storage battery module 11, and uses the acquired characteristic information to store the storage battery module 11. Select suitable control conditions. When the characteristic information is a charging current value, the storage battery management device 30 controls a smaller current value among the first maximum charging current value and the second maximum charging current value acquired from the one storage battery module 11. Select as a condition. Furthermore, when the characteristic information is a discharge current value, the storage battery management device 30 uses a smaller current value among the first maximum discharge current value and the maximum discharge current value acquired from the storage battery module 11 as a control condition. select.

  Moreover, although the storage battery management apparatus 30 of this modification selected the electric current value for charge control using each 1st largest charging current value and the 2nd largest charging current value, it is not limited to this. The storage battery management device 30 may select a charge control current value from each first maximum charge current value. In this case, the power supply control device 40 compares the current value for charge control with the maximum charging current value stored in itself, selects a current value with a small value, and uses each selected storage battery to store each storage battery. Control charging of the module 11. Further, the storage battery management device 30 may select a current value for discharge control from each first maximum discharge current value. In this case, the power supply control device 40 compares the current value for discharge control with the maximum discharge current value stored in itself, selects a current value with a small value, and uses each selected storage battery for each storage battery. The discharge of the module 11 is controlled.

  As described above, in the present modification, the characteristic information represents the maximum charging current value (first maximum charging current value) that can be input by the storage battery module 11 during charging. It is preferable that the processing unit 33 selects the minimum charging current value among the maximum charging current values acquired by the characteristic information acquisition unit 31 as the charging limit value.

  According to this configuration, the storage battery management device 30 can select a charging current value that matches all of the plurality of storage battery modules 11.

  Further, the characteristic information represents a maximum discharge current value (first maximum discharge current value) that can be output by the storage battery module 11 during discharge. The processing unit 33 preferably selects the minimum discharge current value as the discharge limit value among the maximum discharge current values acquired by the characteristic information acquisition unit 31.

  According to this configuration, the storage battery management device 30 can select a discharge current value that is suitable for all of the plurality of storage battery modules 11.

  In addition, the storage battery management device 30 further determines the maximum charging current value (second maximum charging current value) that the power supply control device 40 can input to each of the plurality of storage battery modules 11 when charging the plurality of storage battery modules 11. A current value acquisition unit 35 that is acquired from the power supply control device is provided. It is preferable that the processing unit 33 selects a small current value as a control condition among the selected charge limit value and the maximum charge current value.

  According to this configuration, the storage battery management device 30 can set an optimal current value when charging the plurality of storage battery modules 11.

  In addition, the storage battery management device 30 further determines the maximum discharge current value (second maximum discharge current value) that the power supply control device 40 can input from each of the plurality of storage battery modules 11 when discharging the plurality of storage battery modules 11. A current value acquisition unit 35 acquired from the power supply control device 40 is provided. It is preferable that the processing unit 33 selects a small current value as a control condition among the selected discharge limit value and the maximum discharge current value.

  According to this configuration, the storage battery management device 30 can set an optimal current value when discharging the plurality of storage battery modules 11.

3 Modification 2 of Embodiment 1
In the first embodiment, the storage battery management device 30 selects the fully charged voltage value according to the battery temperature, but is not limited thereto. The storage battery management device 30 may select a fully charged voltage value according to the set control mode in addition to the function of selecting a fully charged voltage value according to the battery temperature.

  The power supply control device 40 is set to one control mode among a plurality of control modes in order to control charging of each storage battery module 11. Here, the plurality of control modes include a normal mode, a long life mode, and a self-supporting mode. The normal mode is a mode for always charging 100% of the power amount without limiting the amount of power charged in the storage battery module 11 regardless of the battery temperature of each storage battery module 11. The long life mode is a mode in which the amount of power to be charged is limited in order to extend the life of the storage battery module 11. For example, in the long life mode, the upper limit of the amount of power to be charged is limited. The self-supporting mode is a mode for achieving both the normal mode and the long life mode. As described in the first embodiment, the fully charged voltage value is selected according to the battery temperature.

  The storage battery management device 30 determines the mode set as the control mode at the start of charging. When the control mode is the normal mode, the storage battery management device 30 selects the above-described normal voltage value as control information. When the control mode is the long life mode, the storage battery management device 30 selects the above-described limit voltage value as control information. When the control mode is the self-sustained mode, it is the same as that of the first embodiment, and thus description thereof is omitted here. When the control mode is the long life mode, the storage battery management device 30 uses the limit voltage value as the control information, but is not limited to this. The storage battery management device 30 may select a voltage value lower than the normal voltage value as the control information.

  Further, in the present modification, the storage battery module 11 further includes the voltage value used in the normal mode as the third full charge condition and the voltage value used in the long life mode as the fourth full charge condition, further included in the characteristic information, Delivered to the storage battery management device 30.

4 Embodiment 2
In the first embodiment, each storage battery module 11 delivers a plurality of full charge conditions (first full charge condition, second full charge condition) to the storage battery management device 30, but in this embodiment, each storage battery module 11 has one The difference is that the full charge condition is transferred to the storage battery management device 30.

  In the following, the present embodiment will be described focusing on differences from the first embodiment. In addition, the same code | symbol is attached | subjected to the component similar to Embodiment 1, and description is abbreviate | omitted suitably.

  As shown in FIG. 6, the power storage system 1 of the present embodiment includes a storage battery system 10 including a plurality of storage battery modules 11 and a control device 20.

  Each of the storage battery modules 11 according to the present embodiment passes the characteristic information representing the characteristics of the storage battery module 11, which is information corresponding to the battery temperature of the storage battery module 11, to the control device 20.

  When the control device 20 of the present embodiment acquires the characteristic information from the plurality of storage battery modules 11, the control device 20 selects a control condition suitable for the storage battery module 11 from the acquired characteristic information. The control device 20 controls at least one of charging and discharging of each storage battery module 11 based on the selected control condition. Hereinafter, a case where the control condition is a condition related to charging will be described.

(Storage battery module 11)
Each of the plurality of storage battery modules 11 includes a storage battery 12, a temperature sensor 13, a storage unit 14, an output unit 15, and a determination unit 16, as shown in FIG. The storage battery module 11 has a processor and a memory, and the function of the determination unit 16 of the storage battery module 11 is realized by the processor executing a program stored in the memory. This program is provided through a telecommunication line such as the Internet, or is provided by a computer-readable recording medium.

  The determination unit 16 determines a full charge condition to be transmitted to the storage battery management device 30. Specifically, the determination unit 16 determines whether or not the battery temperature measured by the temperature sensor 13 is higher than a predetermined threshold value. The determination unit 16 determines the normal voltage value as the full charge condition when determining that the battery temperature is higher than the predetermined threshold value, and satisfies the limit voltage value when determining that the battery temperature is equal to or lower than the predetermined threshold value. Determine the charging conditions.

  The output unit 15 delivers the full charge condition as characteristic information. Specifically, every time the full charge condition to be transmitted to the storage battery management device 30 is determined by the determination unit 16, the output unit 15 delivers the determined full charge condition to the control device 20 as characteristic information.

  In addition, the some storage battery module 11 is electrically connected by connecting each storage battery 12 in series similarly to Embodiment 1. FIG.

(Control device 20)
The control device 20 is a power conditioner that charges each storage battery module 11 using external power, for example, generated power of the solar cell 50, and as shown in FIG. 6, the storage battery management device 30 and the power control device 40. With.

  As shown in FIG. 6, the storage battery management device 30 includes a characteristic information acquisition unit 31, a processing unit 33, and a notification unit 34. The storage battery management device 30 includes a processor and a memory, and each function of the storage battery management device 30 is realized by the processor executing a program stored in the memory. This program is provided through a telecommunication line such as the Internet, or is provided by a computer-readable recording medium.

  The characteristic information acquisition unit 31 acquires characteristic information that is a full charge condition from each storage battery module 11 at the start of charging.

  The processing unit 33 uses the characteristic information acquired by the characteristic information acquisition unit 31 to select a control condition that matches the plurality of storage battery modules. Specifically, the processing unit 33 selects, as the control condition, the lowest voltage value among the voltage values represented by each of the characteristic information (full charge condition) output for each storage battery module 11.

  The notification unit 34 notifies the power supply control device 40 of the control condition in order to control each storage battery module 11 based on the control condition selected by the processing unit 33.

  Since the function of the power supply control device 40 of the present embodiment is the same as that of the first embodiment, description thereof is omitted here.

  Next, the operation for determining the characteristic information that the storage battery module 11 should output to the storage battery management device 30 and the operation for the storage battery management device 30 to determine the control conditions will be described using the flowcharts shown in FIGS. .

  FIG. 8 is a flowchart illustrating an operation for determining the characteristic information that the storage battery module 11 should output to the storage battery management device 30.

  The determination part 16 of the storage battery module 11 determines the full charge conditions which should be transmitted to the storage battery management apparatus 30 (step S150). Specifically, when the battery temperature measured by the temperature sensor 13 is higher than a predetermined threshold, the determination unit 16 determines the normal voltage value as the full charge condition, and the battery temperature is equal to or lower than the predetermined threshold. In this case, the limit voltage value is determined as a full charge condition. The output unit 15 delivers the full charge condition determined by the determination unit 16 to the control device 20 as characteristic information (step S155).

  FIG. 9 is a flowchart illustrating an operation in which the storage battery management device 30 determines a control condition.

  The characteristic information acquisition unit 31 of the storage battery management device 30 acquires characteristic information from the plurality of storage battery modules 11 (step S200). The processing unit 33 of the storage battery management device 30 uses the characteristic information acquired by the characteristic information acquisition unit 31 to perform a selection process for selecting a control condition suitable for the plurality of storage battery modules 11 (step S205). Specifically, the processing unit 33 selects the lowest voltage value among the voltage values represented by each characteristic information (full charge condition) as a control condition. The notification unit 34 of the storage battery management device 30 notifies the power supply control device 40 of the control condition selected by the processing unit 33 (step S210). The power supply control device 40 controls the voltage when each storage battery module 11 is fully charged based on the control condition notified by the notification unit 34.

  The storage battery management device 30 of the present embodiment acquires the characteristic information at the start of charging, but is not limited to this. Similarly to the first embodiment, the storage battery management device 30 of the present embodiment may acquire the characteristic information at a predetermined cycle (for example, every 3 hours). In addition, this numerical value is an example, Comprising: It is not the meaning limited to these numerical values.

  Moreover, although each storage battery 12 shall be connected in series, parallel connection may be sufficient and the connection in which serial connection and parallel connection were mixed may be sufficient.

  In the present embodiment, the voltage value is used as the full charge condition, but the present invention is not limited to this. A charging rate (SOC) may be used as a full charge condition. For example, when the battery temperature measured by the temperature sensor 13 is higher than a predetermined threshold, the determination unit 16 determines the charging rate as 100%. When the battery temperature is equal to or lower than the predetermined threshold, the determination unit 16 determines the charging rate as 80%. The storage battery management device 30 selects the lowest charging rate among the charging rates determined for each of the plurality of storage battery modules 11 and notifies the power supply control device 40 of the selected charging rate. At this time, each of the plurality of storage battery modules 11 includes a measurement circuit that measures the charging rate of the storage battery 12. The power supply control device 40 controls the charging of each storage battery module 11 so that the charging rate notified from the storage battery management device 30 is obtained based on the results measured by the respective measurement circuits of the plurality of storage battery modules 11. .

  As described above, in the present embodiment, the characteristic information represents the full charge condition related to the determination of the full charge of the storage battery module 11. It is preferable that the process part 33 selects the single full charge condition which adapts with respect to the some storage battery module 11 among each full charge conditions as a control condition.

  According to this configuration, the storage battery management device 30 can set the full charge condition relating to the determination of full charge that is suitable for the plurality of storage battery modules 11.

  Here, the full charge condition is a condition representing a voltage value at the time of full charge. The processing unit 33 preferably selects the full charge condition representing the lowest voltage value among the full charge conditions acquired by the characteristic information acquisition unit 31.

  According to this configuration, the storage battery management device 30 can set a voltage value at the time of full charge that matches all of the plurality of storage battery modules 11.

  In addition, the storage battery module 11 according to one aspect of the present invention includes the storage battery 12, the storage unit 14 that stores characteristic information for at least one of charging and discharging, and the storage battery management device that manages the characteristic information. And an output unit 15 for delivering the data.

  According to this configuration, the storage battery module 11 can cause the storage battery management device 30 to perform control such as charging under appropriate conditions even when the operator forgets the information setting operation.

  Here, the storage unit 14 stores a plurality of characteristic information. Each of the plurality of characteristic information is a value related to determination of full charge, and is a voltage value according to the operating environment. The storage battery module 11 further includes a determination unit 16 that determines one voltage value from each voltage value according to the operating environment. The output unit 15 preferably passes the voltage value determined by the determination unit 16.

  According to this configuration, the storage battery module 11 can deliver an optimum voltage value at the time of full charge according to the operating environment.

  Here, the operating environment is the battery temperature of the storage battery module 11. It is preferable that the determination part 16 determines one voltage value according to battery temperature among each voltage value.

  According to this configuration, the storage battery module 11 can deliver an optimum voltage value at full charge according to the battery temperature.

5 Modification 1 of Embodiment 2
Here, as in the first modification of the first embodiment, at least one of the charging current value and the discharging current value is used as the control condition. Hereinafter, the points different from the second embodiment will be mainly described. In this modification, the same components as those in the second embodiment are denoted by the same reference numerals, and description thereof will be omitted as appropriate.

  As shown in FIG. 10, the power storage system 1 of this modification includes a storage battery system 10 including a plurality of storage battery modules 11 and a control device 20.

  Each storage battery module 11 includes a storage battery 12, a temperature sensor 13, a storage unit 14, an output unit 15, and a determination unit 16 (see FIG. 7). The storage battery module 11 has a processor and a memory, and the function of the determination unit 16 of the storage battery module 11 is realized by the processor executing a program stored in the memory. This program is provided through a telecommunication line such as the Internet, or is provided by a computer-readable recording medium.

  The storage unit 14 stores a maximum charging current value (first charging current value) and a maximum discharging current value (first discharging current value) when the battery temperature is higher than a predetermined threshold. The storage unit 14 further stores a maximum charging current value (second charging current value) and a maximum discharging current value (second discharging current value) when the battery temperature is equal to or lower than a predetermined threshold.

  The determination unit 16 determines characteristic information to be transmitted to the storage battery management device 30. Specifically, the determination unit 16 determines whether or not the battery temperature measured by the temperature sensor 13 is higher than a predetermined threshold value. When determining that the battery temperature is higher than the predetermined threshold, the determining unit 16 acquires the first charging current value and the first discharging current value from the storage unit 14. When determining that the battery temperature is equal to or lower than the predetermined threshold, the determination unit 16 acquires the second charging current value and the second discharging current value from the storage unit 14. In addition, when it is not necessary to distinguish between the first charging current value and the second charging current value, these are collectively referred to as a first maximum charging current value. Moreover, when it is not necessary to distinguish between the first discharge current value and the second discharge current value, these are collectively referred to as a second maximum discharge current value.

  The output unit 15 delivers each of the first maximum charging current value and the first maximum discharging current value acquired by the determination unit 16 to the control device 20 as characteristic information.

  Next, the control device 20 of this modification will be described.

  As illustrated in FIG. 10, the control device 20 includes a storage battery management device 30 and a power supply control device 40. As shown in FIG. 10, the storage battery management device 30 includes a characteristic information acquisition unit 31, a processing unit 33, a notification unit 34, and a current value acquisition unit 35.

  The characteristic information acquisition unit 31 acquires the charging current value and the discharging current value output from each storage battery module 11 as characteristic information.

  The current value acquisition unit 35 acquires a second maximum charging current value from the power supply control device 40 when the power supply control device 40 controls charging of each storage battery module 11. In addition, the current value acquisition unit 35 acquires a second maximum discharge current value from the power supply control device 40 when the power supply control device 40 controls the discharge of each storage battery module 11.

  When controlling the charging of each storage battery module 11, the processing unit 33 uses the first maximum charging current value acquired by the characteristic information acquisition unit 31 to set a control condition suitable for the plurality of storage battery modules 11. select. When controlling the discharge of each storage battery module 11, the processing unit 33 uses the first maximum discharge current value acquired by the characteristic information acquisition unit 31 to set a control condition suitable for the plurality of storage battery modules 11. select. For example, the processing unit 33 selects a minimum current value (charge limit value) from among the first maximum charge current values, and a smaller current value (charge) between the selected charge limit value and the second maximum charge current value. Control current value) is selected as a control condition. In addition, the processing unit 33 selects a minimum discharge current value (discharge limit value) from among the first maximum discharge current values, and selects a smaller current value (the selected discharge limit value) and the second maximum discharge current value ( The discharge control current value) is selected as the control condition.

  The notification unit 34 notifies the power supply control device 40 of the control condition in order to control each storage battery module 11 based on the control condition selected by the processing unit 33.

  When the control condition is a current value for charge control, the power supply control device 40 controls the charging of each storage battery module 11 based on the current value represented by the control condition. When the control condition is the current value for discharge control, the power supply control device 40 controls the discharge of each storage battery module 11 based on the current value represented by the control condition.

  Next, the operation for determining the characteristic information that each storage battery module 11 of this modification should output to the storage battery management device 30 will be described with reference to the flowcharts shown in FIGS. 11 and 12. In addition, since the operation | movement which the storage battery management apparatus 30 of this modification determines a control condition can be implement | achieved by the operation | movement shown in each of FIG. 4, FIG.

  First, the operation for determining the charging current value as the characteristic information will be described with reference to the flowchart shown in FIG.

  The determination unit 16 of the storage battery module 11 determines the first maximum charging current value to be transmitted to the storage battery management device 30 (step S250). Specifically, when the battery temperature measured by the temperature sensor 13 is higher than a predetermined threshold, the determination unit 16 determines the first charging current value as the first maximum charging current value to be transmitted. When the battery temperature is equal to or lower than the predetermined threshold, the determination unit 16 determines the second charging current value as the first maximum charging current value to be transmitted.

  The output unit 15 delivers the first maximum charging current value determined by the determination unit 16 to the control device 20 as characteristic information (step S255).

  Next, the operation for determining the discharge current value as the characteristic information will be described with reference to the flowchart shown in FIG.

  The determination part 16 of the storage battery module 11 determines the 1st largest discharge current value which should be transmitted to the storage battery management apparatus 30 (step S300). Specifically, when the battery temperature measured by the temperature sensor 13 is higher than a predetermined threshold, the determination unit 16 determines the first discharge current value as the first maximum discharge current value to be transmitted. When the battery temperature is equal to or lower than a predetermined threshold, the determination unit 16 determines the second discharge current value as the first maximum discharge current value to be transmitted.

  The output unit 15 delivers the first maximum discharge current value determined by the determination unit 16 to the control device 20 as characteristic information (step S305).

  As described in the first modification of the first embodiment, the storage battery management device 30 according to the present modification uses the charge control current value from each first maximum charge current value, and the discharge control current from each first maximum discharge current value. Each value may be selected. The power supply control device 40 in this case is the same as the power supply control device 40 described in the second modification of the first embodiment, and thus description thereof is omitted here.

6 Modification 2 of Embodiment 2
In the second embodiment, each storage battery module 11 outputs the full charge condition determined according to the battery temperature as characteristic information to the storage battery management device 30, but is not limited thereto. Each storage battery module 11 includes the full charge condition determined according to the battery temperature in the characteristic information, and as described in the second modification of the first embodiment, the full charge according to each of the normal mode and the long life mode. The voltage value of the hour may be included.

  In this case, the storage battery management device 30 of the present modification selects, for example, a normal voltage value as control information when the control mode is the normal mode, as in the second modification of the first embodiment. When the control mode is the long life mode, the storage battery management device 30 selects, for example, a limit voltage value as control information. When the control mode is the self-sustained mode, it is the same as that of the second embodiment, and thus description thereof is omitted here. When the control mode is the long life mode, the storage battery management device 30 uses the limit voltage value as the control information, but is not limited to this. The storage battery management device 30 may select a voltage value lower than the normal voltage value as the control information.

  Further, in the present modification, the storage battery module 11 passes the voltage value used in the normal mode and the voltage value used in the long life mode to the storage battery management device 30 by further including the characteristic information.

7 Other Modifications Although the present invention has been described above based on each embodiment, the present invention is not limited to the above-described embodiment and modification. For example, the following modifications can be considered.

  (1) In each of the above embodiments, the power supply control device 40 charges each storage battery module 11 using the generated power of the solar battery 50, but is not limited to this.

  The power supply control device 40 charges each storage battery module 11 using electric power other than the solar battery 50, for example, electric power generated using natural energy such as wind power, hydraulic power, geothermal heat, or commercial power obtained from a commercial power source. May be.

  (2) In each said embodiment, although each storage battery module 11 was provided with the temperature sensor 13, it is not limited to this. The storage battery system 10 may include one temperature sensor 13. In this case, the storage battery management device 30 sets the battery temperature acquired from one temperature sensor 13 as the temperature of each storage battery module 11 (storage battery 12).

  (3) You may combine the said embodiment and modification.

DESCRIPTION OF SYMBOLS 11 Storage battery module 12 Storage battery 14 Storage part 15 Output part 16 Determination part 30 Storage battery management apparatus 31 Characteristic information acquisition part 32 Discrimination information acquisition part 33 Processing part 34 Notification part 35 Current value acquisition part 40 Power supply control apparatus

Claims (16)

A characteristic information acquisition unit for acquiring characteristic information from the storage battery module;
A storage battery management apparatus comprising: a power supply control apparatus that controls at least one of charging and discharging of the storage battery module; and a notification unit that notifies a control condition based on the characteristic information. There are a plurality of the storage battery modules,
The characteristic information acquisition unit acquires the characteristic information from each of the plurality of storage battery modules,
The storage battery management apparatus according to claim 1, further comprising a processing unit that selects a control condition suitable for the plurality of storage battery modules using each characteristic information acquired by the characteristic information acquisition unit. . The characteristic information includes a plurality of full charge conditions related to determination of full charge,
Furthermore, a discrimination information acquisition unit for acquiring discrimination information for selecting one full charge condition from the plurality of full charge conditions,
The processing unit selects one full charge condition among the plurality of full charge conditions using the determination information for each of the plurality of storage battery modules, and the plurality of storage batteries among the selected full charge conditions. The storage battery management device according to claim 2, wherein a full charge condition suitable for a module is selected as the control condition. The discrimination information is operating environment information related to the operating environment of the storage battery module,
Each of the plurality of full charge conditions is a voltage value at the time of full charge according to the operating environment of the storage battery module,
The processing unit selects one full charge condition among the plurality of full charge conditions using the operating environment information for each of the plurality of storage battery modules, and is the lowest among the selected full charge conditions. The storage battery management device according to claim 3, wherein a full charge condition representing a voltage value is selected. The operating environment information is a battery temperature of the storage battery module,
The discrimination information acquisition unit acquires a battery temperature for each of the plurality of storage battery modules,
The storage battery management device according to claim 4, wherein the processing unit selects, for each of the plurality of storage battery modules, a full charge condition according to a battery temperature of the storage battery module. The characteristic information represents a full charge condition related to a determination of a full charge of the storage battery module,
The storage battery management device according to claim 2, wherein the processing unit selects, as the control condition, one full charge condition suitable for the plurality of storage battery modules among the full charge conditions. The full charge condition is a condition representing a voltage value at the time of full charge,
The storage battery management device according to claim 6, wherein the processing unit selects a full charge condition representing the lowest voltage value from among the full charge conditions acquired by the characteristic information acquisition unit. The characteristic information represents a maximum charging current value that can be input by the storage battery module during charging,
The storage battery management apparatus according to claim 2, wherein the processing unit selects a minimum charging current value as a charging limit value from among the maximum charging current values acquired by the characteristic information acquisition unit. The characteristic information represents a maximum discharge current value that can be output by the storage battery module during discharge,
The storage battery management device according to claim 2, wherein the processing unit selects a minimum discharge current value as a discharge limit value among the discharge current values acquired by the characteristic information acquisition unit. Furthermore, the power supply control device includes a current value acquisition unit that acquires, from the power supply control device, a maximum charging current value that can be input to each of the storage battery modules when charging the storage battery modules.
The storage battery management device according to claim 8, wherein the processing unit selects a smaller current value as the control condition from the selected charging limit value and the maximum charging current value. Furthermore, the power supply control device includes a current value acquisition unit that acquires a maximum discharge current value that can be input from each of the plurality of storage battery modules when the plurality of storage battery modules are discharged, from the power supply control device,
The storage battery management apparatus according to claim 9, wherein the processing unit selects a small current value as the control condition from the selected discharge limit value and the maximum discharge current value. A storage battery management device according to any one of claims 1 to 11, and the power supply control device,
The power supply control device, when receiving the control condition from the storage battery management device, controls the storage battery module based on the control condition. A storage battery,
A storage unit storing characteristic information for at least one of charging and discharging; and
A storage battery module comprising: an output unit that delivers the characteristic information to a storage battery management device that manages the characteristic information. The storage unit stores a plurality of characteristic information,
Each of the plurality of characteristic information is a value related to determination of full charge and is a voltage value according to an operating environment,
According to the operating environment, further comprising a determining unit that determines one voltage value from each voltage value,
The storage battery module according to claim 13, wherein the output unit delivers the voltage value determined by the determination unit. The operating environment is a battery temperature of the storage battery module,
The storage battery module according to claim 14, wherein the determination unit determines one voltage value corresponding to the battery temperature among the voltage values. Characteristic information acquisition processing for acquiring characteristic information from the storage battery module;
A storage battery management method comprising: a notification process for notifying a control condition based on the characteristic information to a power supply control device that controls at least one of charging and discharging of the storage battery module.

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