JP7050260B1 - Charging / discharging control system for storage batteries - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a charge / discharge control system for a storage battery capable of appropriately charging / discharging the storage battery. SOLUTION: A charge / discharge control system 10 is loaded by using at least one of electric power generated by a solar cell module 12, electric power stored in a storage battery 14, and electric power transmitted from a power transmission system (grid) 16. It is a system that supplies power to 18. The charge / discharge control system 10 includes a solar cell module 12, a storage battery 14, a first detection unit 20, a charge / discharge unit 22, a power conversion unit 24, a second detection unit 26, a control unit 28, and a storage unit 30. [Selection diagram] Fig. 1

Description

The present invention relates to a storage battery charge / discharge control system that controls charging and discharging of the storage battery.

The following Patent Document 1 discloses a system that predicts the power generation amount and power consumption of the solar cell on the next day based on the past data and charges the storage battery at night. Patent Document 1 makes it possible to secure a capacity that can store the power generated by the solar cell in the daytime in the storage battery by preventing the storage battery from being charged more than necessary based on the prediction.

However, the power generated by solar cells depends on the weather, and the power consumption depends on human activities. The predicted power generation and power consumption may not exactly match the actual power generation and power consumption. Patent Document 1 may not be able to use the electric power generated by the solar cell for charging, or may overcharge with the electric power from the commercial power grid.

JP 2015-213389

An object of the present invention is to provide a charge / discharge control system for a storage battery capable of appropriately charging / discharging the storage battery.

The charge / discharge control system for a storage battery of the present invention is transmitted from a storage battery that stores electric power, a first detection unit that detects the charge rate of the storage battery, a charge / discharge unit that controls charge / discharge of the storage battery, and a transmission system. As the power supplied to the load by controlling the power conversion unit that converts the incoming power into a predetermined power, the second detection unit that detects the power used in the load, and the charge / discharge unit and the power conversion unit. A control unit that selects either the electric power stored in the storage battery or the electric power transmitted from the transmission system to control the charge / discharge of the storage battery, and a storage unit that stores data including the electric power usage status of the load. Be prepared. The charge rate of the storage battery has a first threshold value for starting charging of the storage battery and a second threshold value for stopping charging of the storage battery, and the control unit detects data stored in the storage unit and the first detection unit detects the data. The first threshold value and the second threshold value are changed based on the charge rate of the storage battery and the power consumption of the load detected by the second detection unit.

According to the present invention, by flexibly changing the first threshold value and the second threshold value, the charging / discharging of the storage battery is controlled, and the charging / discharging of the storage battery can be appropriately performed.

It is a block diagram which shows the structure of the charge / discharge control system of this invention. It is a figure which shows the control when the storage battery is charged by the generated power of a solar cell panel. It is a figure which shows the control when the storage battery is charged by the electric power of a power transmission system. It is a figure which shows the control when the power consumption of a load is large unlike the prediction. It is a figure which shows the control when the power is generated by the solar cell panel unlike the prediction. It is a block diagram which shows the structure of the charge / discharge control system which omitted the solar cell panel. It is a figure which shows the control when the storage battery is charged by the electric power of a power transmission system. It is a figure which shows the control when the power consumption of a load becomes large unlike the prediction. It is a figure which shows the control when the power consumption of a load becomes large unlike the prediction on the way. It is a block diagram which shows the structure of the charge / discharge control system which controls the charge / discharge of a storage battery including the weather condition. It is a block diagram which shows the structure of the charge / discharge control system which includes a communication part.

The charge / discharge control system for the storage battery of the present application will be described with reference to the drawings. Although a plurality of embodiments will be described, the same configuration of one embodiment and another embodiment may be described in one embodiment and the description may be omitted in another embodiment. Each embodiment is not independent and may be combined as appropriate.

[Embodiment 1]
The charge / discharge control system 10 shown in FIG. 1 is loaded by using at least one of the electric power generated by the solar cell module 12, the electric power stored in the storage battery 14, and the electric power transmitted from the transmission system (grid) 16. It is a system that supplies power to 18.

The charge / discharge control system 10 includes a solar cell module 12, a storage battery 14, a first detection unit 20, a charge / discharge unit 22, a power conversion unit 24, a second detection unit 26, a control unit 28, and a storage unit 30. The device of each part is composed of hardware, software, or both that operate as described later.

The solar cell module 12 is a device that generates electricity by being irradiated with sunlight. The generated electric power is stored in the storage battery 14 or consumed by the load 18. The installation location of the solar cell module 12 is not particularly limited, and the solar cell module 12 is installed on a sunny roof or on the ground.

The storage battery 14 charges the electric power generated by the solar cell module 12 and the electric power transmitted from the transmission system 16. If the power generated by the solar cell module 12 is higher than the power consumption of the load 18, the generated power is stored. If the electric power generated by the solar cell module 12 is lower than the electric power consumed by the load 18, the electric power of the power transmission system 16 is stored.

The first detection unit 20 is a circuit or the like for measuring the charge rate (dischargeable amount) of the storage battery 14. The first detection unit 20 measures the terminal voltage of the storage battery 14 to obtain the charge rate, measures the current value at the time of charging and discharging of the storage battery 14 to obtain the charge rate, and adds temperature characteristics and discharge characteristics to the above method. It is possible to use a circuit or the like that uses various methods such as a method for discharging. The detected charge rate is input to the control unit 28.

The charging / discharging unit 22 is a circuit or the like that controls charging and discharging of electric power to the storage battery 14. The charge / discharge unit 22 is controlled by the control unit 28. The charging / discharging unit 22 charges the storage battery 14 with electric power from the solar cell module 12 or the transmission system 16, and discharges the electric power stored in the storage battery 14 so that it can be used by the load 18.

The power conversion unit 24 is a circuit or the like for converting the power consumed by the load 18. For example, the power conversion unit 24 converts the power into power having a frequency and a voltage that can be used by the load 18. At least one electric power of the solar cell module 12, the storage battery 14, or the power transmission system 16 is converted by the power conversion unit 24 and supplied to the load 18. The power conversion unit 24 also converts the power for charging the storage battery 14. The electric power of the solar cell module 12 or the power transmission system 16 is converted by the power conversion unit 24, and the storage battery 14 is charged by the charge / discharge unit 22. The power conversion unit 24 is controlled by the control unit 28. The power conversion unit 24 may have an independent circuit for converting the power of the storage battery 14, a circuit for converting the power of the solar cell module 12, a circuit for converting the power of the transmission system 24, and the like. It may be summarized in.

The second detection unit 26 is a circuit or the like that detects the power consumed by the load 18. A device such as a watt-hour meter may be used for the second detection unit 26. The value detected by the second detection unit 26 is input to the control unit 28.

The control unit 28 is a device that controls the charge / discharge unit 22 and the power conversion unit 24. By controlling the charge / discharge unit 22 and the power conversion unit 24, the power supply to the load 18 and the charge / discharge of the storage battery 14 are controlled. The control unit 28 determines the control method using the value input from the first detection unit 20, the value input from the second detection unit 26, and the data of the storage unit 30.

The storage unit 30 is a device that stores the power usage status data 32 of the load 18 and the power generation status data 34 of the solar cell module 12. These data 32 and 34 are used by the control unit 28. The power usage status data 32 of the load 18 is the past power usage status, and the power generation status data 34 of the solar cell module 12 is the past power generation status.

The system 10 includes a clock unit 36 and a calendar unit 38. The clock unit 36 is a device that transmits the day and time, and the day and time are input to the control unit 28. The calendar unit 38 is a device that stores the sunrise and sunset times of each day and inputs them to the control device 28. By knowing the day, time, sunrise, and sunset time, the generated power of the solar cell module 12 can be predicted. In addition, it is possible to predict human activity by knowing the day and time, and it is also possible to predict the power consumption of the load 18.

Next, the control method performed by the control unit 28 will be described. The control unit 28 controls the charge / discharge unit 22 and the power conversion unit 24 to control the charge / discharge of the storage battery 14.

The horizontal axis of FIG. 2 is time, and the vertical axis is the charge rate (storage rate) of the storage battery 14. The time T1 on the horizontal axis is the time when the power consumption of the load 18 is stopped, the time T2 is the sunset time, the time T3 is the sunrise time, and the time T4 is the time when the power consumption of the load 18 starts.

A on the vertical axis is the first threshold value for starting charging of the storage battery 14, B is the second threshold value for stopping charging of the storage battery 14, and C is the minimum charging rate that does not deteriorate the storage battery 14. By setting the first threshold value A higher than the third threshold value C, it is possible to prevent the storage battery 14 from becoming equal to or lower than the third threshold value C, and to prevent deterioration of the storage battery 14 due to over-discharging. Although the first threshold is changed as described later, it is maintained at a value higher than the third threshold C. The second threshold does not initially set the charge rate to 100%. Since the second threshold value does not reach 100% of the charge rate before the solar cell module 12 generates electricity, the capacity that can be charged in the storage battery 14 is secured.

In FIG. 2, the electric power of the storage battery 14 is discharged and supplied to the load 18 before the time T1 (daytime). At that time, the electric power from the power transmission system 16 is not supplied to the load 18 and is not used for charging the storage battery 14.

The charge rate is set to the first threshold value A at time T1. For example, the control unit 28 predicts the power usage status after the time T1 by using the data 32 of the past power usage status of the load 18 stored in the storage unit 30. It is assumed that there is no power usage of the load 18 from the time T1 to the time T4. Further, it is assumed that after the time T3, the solar cell module 12 generates electricity due to the sunlight, and the power can cover the power consumption of the load 18 and charge the storage battery 14. At time T1, the first threshold value is lowered from A to A1, and the storage battery 14 is not charged.

At time T3, the solar cell module 12 generates electricity due to the sunlight of the sun, and the storage battery 14 starts charging. After the time T4, the electric power generated by the solar cell module 12 is charged to the storage battery 14 while supplying electric power to the load 18. The rate of increase in the charge rate after the time T4 is lower than that between the time T3 and the time T4.

The storage battery 14 is charged with electric power as described above. When the power generated by the solar cell module 12 is not generated or the generated power is lower than the power consumption of the load 18, the charge rate of the storage battery 14 decreases as before the time T1 by discharging the power of the storage battery 14. .. The first threshold value may be returned from A1 to A after the electric power starts to be stored in the storage battery 14 at time T3.

Further, FIG. 3 shows a state of control when the solar cell module 12 does not generate power after the time T3. The power consumption of the load 18 is predicted after the time T4, and the storage battery 14 is charged so as to have a predetermined charge rate, for example, a second threshold value B by calculating back from the time T4. For example, at time T1, the first threshold is lowered from A to A1, and at time T5, the first threshold is returned to A. At time T5, the control unit 28 controls the charge / discharge unit 22 and the power conversion unit 24 to start charging the storage battery 14. At this time, since the solar cell module 12 does not generate electric power, the storage battery 14 is charged with the electric power transmitted from the power transmission system 16.

The charge rate of the storage battery 14 for supplying the required electric power by the load 18 is set to the second threshold value B. The first threshold value is changed from A1 to A at time T5 so that the charge rate of the storage battery 14 becomes the second threshold value B at time T4, and charging is started. At time T4, the control unit 28 controls the charge / discharge unit 22 and the power conversion unit 24, and the storage battery 14 starts discharging.

The charge rate of the storage battery 14 is controlled to be the first threshold value A at time T1. Subsequent charge / discharge control can be predicted at time T1, and then the storage battery 14 can be charged before power is consumed by the load 18.

2 and 3 show the case where the predicted power generation of the solar cell module 12 and the power consumption of the load 18 match the actual power generation and power consumption.

Next, a case where the predicted power generation power and power consumption do not match the actual power generation power and power consumption will be described. FIG. 4 shows a case where the power consumption of the load 18 is different from the predicted one. In FIG. 4, the time T1 to the time T4 are the same as the above description.

As in FIG. 2, the prediction in FIG. 4 is that the storage battery 14 is charged with the electric power generated by the solar cell module 12 after the time T3, and the electric power generated by the solar cell module 12 is supplied to the load 18 after the time T4. While charging the storage battery 14.

Up to time T6, the predicted power generation and power consumption match the actual power generation and power consumption. Further, it is assumed that the first threshold value is A after the time T3.

It is assumed that the power consumption of the load 18 increases after the time T6, and the power consumption of the load 18 exceeds the power generated by the solar cell module 12. The control unit 28 stops charging the storage battery 14, and controls the charge / discharge unit 22 and the power conversion unit 24 so as to discharge the storage battery 14. At this point, the power of the transmission system 16 is not used.

By discharging the storage battery 14 after the time T6, the charge rate of the storage battery 14 decreases. If the discharge is continued in this state, the charge rate of the storage battery 14 is predicted to be equal to or less than the first threshold value A. Therefore, the control unit 28 raises the first threshold value A to A2 and controls the charge / discharge unit 22 and the power conversion unit 24 so as to start charging the storage battery 14.

After the time T7 when the charge rate of the storage battery 14 reaches the threshold value A2, the storage battery 14 is charged. At this time, the storage battery 14 is charged with the electric power transmitted from the power transmission system 16.

The power consumed by the load 18 is predicted, and the second threshold value B is changed so that the charge rate can supply the power to the load 18 according to the prediction. For example, it is predicted that the power consumption of the load 18 will be exhausted at the time T1, and the required power of the load 18 is calculated back from the time T1. For example, if it can be predicted that power can be supplied to the load 18 if the charge rate of the storage battery 14 is B1 at time T8, the second threshold value B is lowered to B1. When the charge rate of the storage battery 14 reaches the threshold value B1 at the time T8, the control unit 28 controls the charge / discharge unit 22 and the power conversion unit 24 so as to discharge the power of the storage battery 14. After time T8, the power of the transmission system 16 is not used. The electric power of the storage battery 14 can be supplied to the load 18. The storage battery 14 can be charged and discharged to supply power to the load 18 without using the power of the power transmission system 16 unnecessarily.

As described above, when the first threshold value and the second threshold value are reached, the control unit 28 switches the control of the charge / discharge unit 22 and the power conversion unit 24 to switch between charging and discharging the storage battery. The control unit 28 constantly or periodically monitors the difference from the prediction from the change in the charge rate of the storage battery 14. If it is different from the prediction, the charge and discharge of the storage battery 14 can be appropriately switched by modifying the power required for the load 18 and changing the first threshold value and the second threshold value.

A case where the power generation forecasts of the solar cell module 12 are different will be described. It is assumed that the solar cell module 12 does not generate electricity the next day after the time T1, and the storage battery is to be charged with the power required by the load 18 by the time T4 (FIG. 5). However, unlike the prediction, it is assumed that the solar cell module 12 generates electricity at time T3. The second threshold value B is raised so that the charge rate becomes 100%, for example. At time T3, charging of the storage battery 14 using the electric power of the power transmission system 16 is stopped, and the electric power generated by the solar cell module 12 is charged to the storage battery 14. After the time T4, the electric power generated by the solar cell module 12 is supplied to the load 18, and the surplus electric power is charged to the storage battery 14.

In order to be able to store the surplus power as described above, the storage capacity of the storage battery 14 is set to be larger than the power consumed by the load 18. For example, when the charge rate of the storage battery 14 becomes the first threshold value and the second threshold value is determined, the second threshold value is set to a value lower than 100%. When surplus power is generated in the generated power of the solar cell module 12, the storage battery 14 can be charged.

After the system 10 is operated, the first threshold value A and the second threshold value B are changed as described above. When there are a plurality of charge / discharge control systems 10, the first threshold value A and the second threshold value B are different for each charge / discharge control system 10.

As described above, the storage battery 14 is charged and discharged by predicting the generated power of the solar cell module 12 and the power consumption of the load 18. When the actual generated power and the power consumption are different, the first threshold A and the second threshold B of the charge rate of the storage battery 14 are changed at all times or at regular intervals to control the charge / discharge unit 22 and the power conversion unit 24. .. As a result, the amount of electric power used from the power transmission system 16 can be reduced, and the generated electric power of the solar cell module 12 can be effectively used.

[Embodiment 2]
It is not limited to switching from discharging to charging when the first threshold is reached. Discharge may be continued even when the first threshold value is reached. For example, in FIG. 4 above, after the first threshold value rises from A to A2, the charge rate drops to A2 at time T9, which is earlier than time T1. If it can be predicted that the third threshold value C will not be lowered by the time T1 even if the storage battery 14 is discharged as it is, the first threshold value is lowered from A2 to A or less so that the storage battery 14 is not charged. The first threshold value may be lowered after the charge rate reaches A2, or the first threshold value may be lowered before that. The control unit 28 appropriately changes the first threshold value according to the prediction.

Further, it was predicted that the charge rate would reach the first threshold value A at the time T1 even when the first threshold value was left at A and not increased, but the power consumption of the load 18 was large and the storage battery was faster than the time T1. The charge rate of 14 may be the first threshold value A. If it is predicted that the charge rate of the storage battery 14 does not fall below the third threshold value C even if the storage battery 14 is discharged until the time T1, the first threshold value A is lowered and the discharge is continued. The power of the transmission system 16 is not used to charge the storage battery 14.

Since the first threshold value A is higher than the third threshold value C, there is a margin in the discharge capacity of the storage battery 12. Even if the charge rate of the storage battery 12 drops to the first threshold value A, discharge can be continued depending on the power used by the load 18. The amount of charge and the number of times of charging using the electric power of the power transmission system 16 can be reduced.

[Embodiment 3]
As shown in FIG. 6, the charge / discharge control system 60 may be the one in which the solar cell module 12 is omitted. Since the solar cell module 12 is omitted, the data 34 of the power generation status of the past solar cell module 12 stored in the storage unit 30 is also omitted.

The time T1, the time T4, and the time T5 shown in FIG. 7 are the same as those in the above embodiment. The power consumption of the load 18 is predicted so that the first threshold value A is reached at the time T1, and the storage battery 14 is charged from the time T5 to the time T4. After the time T4, the storage battery 14 is discharged to supply electric power to the load 18 so that the first threshold value A is reached at the time T1. In the same manner as described above, the power consumption of the load 18 thereafter is predicted at time T1 and charge / discharge is controlled.

A case where the prediction of the power consumption of the load 18 and the prediction of the actual power consumption are different will be described. For example, when the actual power consumption of the load 18 becomes larger than expected, the charge rate of the storage battery 14 decreases faster. As shown in FIG. 8, the first threshold value is raised from A to A3 to accelerate the charging start time.

Further, if the power used by the load 18 becomes larger than expected during discharging and the charging rate reaches the first threshold value A before the prediction is corrected, charging is started (FIG. 9). Predict the required power up to time T1. If the required power is lower than the second threshold B, the second threshold B is lowered to B2, at which point discharge is started.

Even if the solar cell module 12 is omitted, the storage battery 14 is predicted by predicting the power consumption of the load 18 and constantly or periodically changing the first threshold value A and the second threshold value B from the error with the actual power consumption. Charge and discharge. Optimal power will be charged to the storage battery 14.

[Embodiment 4]
When the actual power consumption of the load 18 becomes smaller than expected, the charge rate of the storage battery 14 is higher than the first threshold value A even at the time T1. Charging will not start as it is. The first threshold value A may be increased to the charge rate at that time, and the storage battery 14 may be charged so as to satisfy the power consumption consumed by the load 18 by calculating back from the time T1 at which the power consumption is stopped by the load 18 on the next day. That is, the first threshold value is changed to the actual charge rate at the time T1 when it is predicted that the power consumption of the load 18 will be exhausted, and then the power consumption of the load 18 and the generated power of the solar cell module 12 are predicted, and the first threshold value is obtained. To determine. At that time, if the first threshold value and the charge rate remain the same, charging is started. If there is no need for charging at time T1, the first threshold is lowered until the time when charging is required. Even when the solar cell module 12 is not provided, the power usage status of the load 18 is predicted, and the first threshold value is changed in the same manner.

[Embodiment 5]
The data 32 and 34 stored in the storage unit 30 may be rewritten. The average of the power usage status of the load 18 and the power generation status of the solar cell module in the past for a certain period is obtained, and if it is different from the data 32 and 34, it is rewritten. By rewriting the data 32 and 34, the accuracy of prediction is improved.

The data 32 and 34 may be divided into specific periods such as time, day, day of the week or month. The control unit 28 predicts and controls the above using the date and time data 32 and 34 that match the date and time from the clock unit 36. Since the data 32 and 34 are divided for each specific period, the accuracy of prediction is improved.

Further, instead of rewriting the data 32 and 34, the data 32 and 34 may be added. By adding the data 32 and 34, the data 32 and 34 used by the control unit 28 for the prediction increase, and the accuracy of the prediction can be improved.

[Embodiment 6]
As described above, the first threshold A and the second threshold B are changed by the predicted power generation power and power consumption and the actual power generation power and power consumption. After changing the first threshold value A and the second threshold value B, the first threshold value is returned to A after switching from discharging the storage battery 14 to charging, and after switching from charging to discharging the storage battery 14, the second threshold value is returned to B. May be good. For example, in FIG. 4, after changing the first threshold value from A to A1, the first threshold value may be returned to A after the time T6 has passed. Further, after the second threshold value is changed from B to B1, the second threshold value may be returned to B after the time T7 has passed.

[Embodiment 7]
Like the charge / discharge control system 100 of FIG. 10, the control unit 28 may be provided with a weather unit 102 for inputting weather information. The meteorological unit 102 inputs the current weather, the temperature, or both to the control unit 28 after a certain period of time. The control unit 28 predicts the power generation power of the solar cell module 12 and the power consumption of the load 18 based on the data input from the detection units 20, 26, the storage unit 30, and the meteorological unit 102, and the charge / discharge unit 22 and the power conversion. The unit 24 is controlled. For example, the power generated by the solar cell module 12 depends on the weather, and the power usage of the load 18 (usage status of an air conditioner or the like) depends on the temperature. By using the weather, the temperature, or both for the prediction of the control unit 28, the prediction accuracy is improved.

The sensor 104 may be arranged at or around the load 18. The sensor 104 is a temperature sensor, a humidity sensor, or the like. The information detected by the sensor 104 is input to the control unit 28. The control unit 28 further adds the information of the sensor 104 when making the above prediction. By adding the information of the sensor 104, it becomes easy to predict the power usage status of the load 18.

An optical sensor may be arranged in the vicinity of the solar cell module 12 and the information may be input to the control unit 28. Information on the amount of solar radiation is input to the control unit 28 and used for predicting the generated power of the solar cell module 12, so that the prediction accuracy of the generated power of the solar cell module 12 can be improved.

For the above weather information and sensors, the weather data and optical sensors may be omitted in the case of the system 60 without the solar cell module 12.

[Embodiment 8]
In the above embodiment, the power usage status data 32 of the load 18 stored in the storage unit 30 and the power generation status data 34 of the solar cell module are past data. The systems 10, 60, 100 of the present application are not limited to past data. For example, if the power usage of the load 18 is fixed, the data 32 of the specific power usage status may be stored.

[Embodiment 9]
Like the charge / discharge control system 110 of FIG. 11, a communication unit 112 that communicates signals of the first detection unit 20 and the second detection unit 26 input to the control unit 28 may be provided. The communication unit 112 is connected to the network 114, and transmits the charge rate of the storage battery 14 and the power used by the load 18 to at least one of the administrator's server, computer, or mobile device connected to the network 114. The administrator can remotely check the operating status of the system 110. Further, the transmitted data may include the power used by the load 18 predicted by the control unit 28 and the power generated by the solar cell module 12.

[Embodiment 10]
The load 18 is not limited to one, and there may be a plurality of loads 18. A storage battery 14, a first detection unit 20, a charge / discharge unit 22, a power conversion unit 24, and a second detection unit 26 may be provided for each load 18, or one storage battery 14 and a first detection unit for a plurality of loads 18. 20, a charge / discharge unit 22, a power conversion unit 24, and a second detection unit 26 may be provided. When there are a plurality of storage batteries 18 and the like, the control unit 28 monitors the charge rate for each storage battery 18 and performs the above-mentioned charging and discharging.

[Embodiment 11]
Although the above embodiment has described the case where the load 18 does not consume power between the time T1 and the time T4, the power may be consumed by the load 18 between the time T1 and the time T4. Charging / discharging to the storage battery 14 is controlled based on the prediction of the power consumption of the load 18 and the generated power of the solar cell module 12. At that time, if the power consumption and the generated power are different from the predictions, the first threshold value A and the second threshold value B are changed to control the charging / discharging of the storage battery 14.

In the above embodiment, since the power consumption in the load 18 disappears at the time T1, the storage battery 14 is charged / discharged so that the charge rate of the storage battery 14 becomes the first threshold value at the time T1. When there is no time for the power consumption of the load 18 to disappear, the charging / discharging of the storage battery 14 may be controlled so as to predict the time when the power consumption of the load 18 becomes the lowest and to reach the first threshold value at that time.

In addition, the present invention can be carried out in a mode in which various improvements, modifications and changes are made based on the knowledge of those skilled in the art without departing from the gist thereof.

10, 60, 100, 110: Storage battery charging / discharging system 12: Solar cell module 14: Storage battery 16: Transmission system 18: Load 20: First detection unit 22: Charging / discharging unit 24: Power conversion unit 26: Second detection unit 28: Control unit 30: Storage unit 32, 34: Data 36: Clock unit 38 Calendar unit 102: Meteorological unit 104: Sensor 112: Communication unit 114: Network

Claims (4)

A storage battery that stores electric power and
The first detection unit that detects the charge rate of the storage battery and
A charging / discharging unit that controls charging / discharging of the storage battery,
A power conversion unit that converts the power transmitted from the power grid into predetermined power,
The second detector that detects the power used by the load,
By controlling the charge / discharge unit and the power conversion unit, either the power stored in the storage battery or the power transmitted from the transmission system is selected as the power to be supplied to the load, and the charge / discharge of the storage battery is controlled. Control unit and
A storage unit that stores data including the power usage status of the load, and
Equipped with
In the charge rate of the storage battery, the storage battery has a first threshold value for starting charging and a second threshold value for stopping charging of the storage battery.
The control unit changes the first threshold value and the second threshold value based on the data stored in the storage unit, the charge rate of the storage battery detected by the first detection unit, and the power consumption of the load detected by the second detection unit. Charging / discharging control system for storage batteries. The charge rate of the storage battery is the lowest charge rate that does not deteriorate the storage battery, and has a third threshold value lower than the first threshold value.
When the charge rate of the storage battery reaches the first threshold value, the control unit determines the data stored in the storage unit, the charge rate of the storage battery detected by the first detection unit, and the power consumption of the load detected by the second detection unit. The charge / discharge control system for a storage battery according to claim 1, wherein the first threshold value is changed based on the above. Equipped with a solar cell module that generates electricity from sunlight,
The storage unit stores data including the power generation status of the solar cell module, and stores the data.
The charge / discharge control system for a storage battery according to claim 1 or 2, wherein the charge / discharge unit charges the storage battery by using the electric power generated by the solar cell module and the electric power transmitted from the power transmission system. The charge / discharge control system for a storage battery according to claim 3, wherein the second threshold value before power is generated by the solar cell module is lower than the charge rate of the storage battery of 100%.

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