JP2012010549A - Electric power standardization system - Google Patents

Abstract

A power leveling system capable of suppressing power outage without increasing a threshold of a leveling control device is provided.
The disclosed system is a power leveling system in which each of a plurality of facilities includes a leveling control device that performs power leveling of power consumption of a load and a power storage device. The power leveling system includes a standby power storage device and a control device. The reserve power storage device assists power supply to a power storage device in which the measured value of the remaining power storage is less than the predicted value among the power storage devices in a plurality of facilities. The control device resets the thresholds of the leveling control devices of the plurality of facilities based on the respective remaining power amounts of the power storage devices and the standby power storage devices of the plurality of facilities.
[Selection] Figure 2

Description

  The present invention relates to a power leveling system that performs power leveling.

In general, power consumption increases during the day and decreases at night. The basic electricity charge is determined by the peak power consumption of the grid power supply. Therefore, in order to suppress the peak of power consumption of the system power supply during the day, it has been proposed to perform power leveling that makes the power consumption of the system power supply uniform throughout the day. For example, if a part of the power consumption of a load during the day is supplied from a power storage device charged at night, the power leveling can be achieved without reducing the total power consumption of the system power supply for one day. It is possible (Patent Document 1). If peak power is suppressed by power leveling, not only can electricity charges be reduced, but the scale of power distribution facilities can be reduced, and CO ₂ emissions can be reduced by improving the nighttime power utilization rate.

JP 2001-258176 A

  By the way, as a specific method of power leveling, when the power consumption of the load becomes larger than the threshold value, the increased power is discharged from the power storage device, and the power consumption of the load becomes smaller than the threshold value. In such a case, there is a method of charging the power storage device with the reduced power.

  When leveling the total power consumption in multiple loads, in principle, if a single power storage device can be inserted in parallel with the grid power supply in the backbone of the multiple load wires, a single load and a single load Equivalent to power leveling in the combination of power storage devices. According to this, assuming a single load having a power consumption equal to the total power consumption of a plurality of loads, the power leveling is performed using the single load and a single power storage device. It is possible to determine a threshold for leveling.

  On the other hand, even in the case of a system in which a plurality of power storage devices are present and each is combined with a load, power leveling in the entire system is possible. However, in that case, even if charging / discharging in each combination is optimized, it does not necessarily optimize the entire system. In order to optimize power leveling of the entire system, it is required to perform control according to individual power consumption and the remaining power of the power storage device.

  Here, in power leveling, the threshold is set in advance according to the capacity of the power storage device and the predicted power consumption pattern. When the actual power consumption pattern completely coincides with the prediction, it is possible to perform an appropriate power leveling operation by using a threshold value that is optimal for the predicted power consumption pattern.

  However, when performing power leveling, complete prediction is difficult, and a deviation occurs between the predicted value of the power consumption of the load and the actually measured value. When the actual measurement value of the power consumption of the load exceeds the predicted value, power is cut off and leveling becomes impossible, and the power consumption of the system power supply may jump up. In order to prevent this when performing power leveling of the entire system, it is only necessary to provide a margin for the threshold of the entire system or to provide a margin for the capacity of all power storage devices in the system. However, an increase in the threshold of the entire system and an increase in the storage capacity cause a significant increase in power charges and device costs, respectively.

  The disclosed system is a power leveling system in which a power leveling control device that performs power leveling of power consumption of a load and a power storage device are provided in each of a plurality of facilities, the power storage device of the plurality of facilities Among them, a standby power storage device that assists in power supply to a power storage device whose measured value of the remaining power storage is less than a predicted value, and the power storage devices of the plurality of facilities and the power storage remaining power of each of the standby power storage devices And a control device for resetting threshold values of the leveling control devices of the plurality of facilities.

  The disclosed system is a power leveling system in which each of a plurality of facilities includes a leveling control device that performs power leveling of load power consumption and a power storage device. The power leveling system includes a standby power storage device and a control device. The reserve power storage device assists power supply to a power storage device in which the measured value of the remaining power storage is less than the predicted value among the power storage devices in a plurality of facilities. The control device resets the thresholds of the leveling control devices of the plurality of facilities based on the respective remaining power amounts of the power storage devices and the standby power storage devices of the plurality of facilities.

  According to the disclosed system, power outage can be suppressed without increasing the threshold value of the leveling control device, and the power storage device can be provided with no capacity margin, thereby reducing cost.

It is a schematic diagram which shows an example of the apparatus structure of the power leveling system which concerns on embodiment. It is a block diagram which shows an example of the apparatus structure of the power leveling system which concerns on embodiment. It is a schematic diagram which shows an example of the concept of electric power leveling control. It is a schematic diagram which shows an example of charging / discharging control of each plant | facility in the case of whole leveling control. It is an example of the whole flowchart of a whole leveling control process. It is an example of the flowchart of a whole leveling control process when a reserve electrical storage apparatus is connected. It is a schematic diagram which shows the example of the other function of a connection port. It is a mimetic diagram showing an example of a modification of a power leveling system concerning an embodiment. It is a mimetic diagram showing an example of a modification of a power leveling system concerning an embodiment.

  Hereinafter, an exemplary embodiment will be described with reference to the drawings.

[Device configuration]
First, an example of a device configuration of the power leveling system 200 according to the embodiment will be described with reference to FIGS. 1 and 2. 1 and 2, the solid line indicates the flow of power, and the broken line indicates the flow of control signals.

  As shown in FIG. 1, the power leveling system 200 mainly includes power storage devices 10 a to 10 c provided in the facilities Ha to Hc, a standby power storage device 20, and a control server 100. The power storage devices 10a to 10c and the standby power storage device 20 are devices including so-called storage batteries and capacitors that can be charged and discharged.

  FIG. 2 shows a detailed block diagram of the apparatus configuration of the power leveling system 200 shown in FIG. Each facility has a leveling control device and a power storage device. Each facility is connected to a system power source, which is a commercial distribution network owned by an electric power company. In each facility, the system power supply and the power storage device are connected to a device that consumes power, that is, one or more home appliances, that is, a load, via the leveling control device.

  The facility Ha is provided with a leveling control device 30a and a power storage device 10a. The system power supply and the power storage device 10a are connected to the load of the facility Ha via the leveling control device 30a. Here, the power storage device 10a is connected to the leveling control device 30a via the connection port 40a.

  The facility Hb is provided with a leveling control device 30b and a power storage device 10b. The system power supply and the power storage device 10b are connected to the load of the facility Hb via the leveling control device 30b. Here, the power storage device 10b is connected to the leveling control device 30b via the connection port 40b.

  The facility Hc is provided with a leveling control device 30c and a power storage device 10c. The system power supply and the power storage device 10c are connected to the load of the facility Hc via the leveling control device 30c. Here, the power storage device 10c is connected to the leveling control device 30c through the connection port 40c.

  The leveling control devices 30a to 30c in the facilities Ha to Hc are connected to the control server 100 via the control information network, and are controlled by the control server 100. The control server 100 is connected to an information DB (database) 110. The leveling control devices 30 a to 30 c transmit information on the power consumption and the remaining amount of power storage of the power storage devices 10 a to 10 c to the control server 100. The control server 100 causes the information DB 110 to store information on the power consumption and the remaining amount of power stored in the power storage devices 10a to 10c. Based on the information, the control server 100 transmits a control signal to the leveling control devices 30a to 30c in order to realize power leveling of the entire system. Each of the leveling control devices 30 a to 30 performs leveling control of the power consumption of the load in each facility Ha to Hc based on the control signal received from the control server 100. Therefore, the control server 100 functions as a control device.

  The spare power storage device 20 is connected to the connection switching port 50. Based on a control signal from the control server 100, the connection switching port 50 connects the standby power storage device 20 to any one of the connection ports 40a to 40c of the facilities Ha to Hc, or connects the standby power storage device 20 to the connection port. To block more. As described above, the connection ports 40a to 40c of the facilities Ha to Hc are connected to the leveling control devices 30a to 30c of the facilities Ha to Hc, respectively. Therefore, the control server 100 can connect the standby power storage device 20 to any of the leveling control devices 30a to 30c by controlling the connection switching port 50. Therefore, the connection switching port 50 functions as a connection switching device.

  In addition, below, when it does not distinguish each component about each component Ha-Hc of the electric power leveling system 200, an alphabetic letter shall be abbreviate | omitted and shown. For example, in the following, when the leveling control devices 30a to 30c are not distinguished from each other, the leveling control devices 30a to 30c are simply indicated as the “leveling control device 30”.

  As described above, the leveling control device 30 performs power leveling control for discharging or charging the power storage device 10 according to the power consumption of the load. The concept of power leveling control is shown in FIG. As shown in FIG. 3, as the power leveling control, the leveling control device 30 discharges the power storage device 10 when the power consumption of the load becomes larger than the threshold, and the power consumption of the load is lower than the threshold. When it becomes smaller, the power storage device 10 is charged. That is, the leveling control device 30 performs charge / discharge control of the power storage device 10 according to the power consumption of the load and the threshold value. In FIG. 3, hatched area portions Ad and Ac correspond to the discharge amount and the charge amount of the power storage device 10, respectively.

  Here, in the power leveling control for all facilities (hereinafter referred to as “total leveling control”), the total power consumption of loads of all facilities is leveled. Specifically, the threshold value of the leveling control device 30 of each facility is adjusted so that the remaining amount of electricity stored in each facility is uniform.

  An example of charge / discharge control of the power storage device 10 in each facility when the overall leveling control is performed will be described with reference to FIG. FIG. 4A shows a state of charge / discharge control of the power storage device 10 in each facility in a state where the spare power storage device 20 is not added, and FIG. 4B shows each state where the standby power storage device 20 is added. The state of the charge / discharge control of the power storage device 10 in the facility is shown.

  While charging / discharging control of the power storage device 10 is being performed, the control server 100 measures the remaining power storage amount of the power storage device 10 in each facility in real time, and the measured value of the measured remaining power storage amount is more than the predicted value. Judge whether or not it is below. Here, the predicted value is based on the average value of the remaining amount of electricity stored at the same time that the actual measurement value was measured for each day in the past fixed period. It is set to be uniform. This is because the leveling effect equivalent to the case of using a single power storage device can be obtained by making the remaining power of all power storage devices uniform. 4A and 4B, changes in the predicted value are indicated by broken line graphs Ga to Gc (hereinafter referred to as “predicted remaining amount curve”). In FIGS. 4A and 4B, the solid line graphs show changes in measured values.

  In the example shown in FIG. 4 (a), the measured value of the remaining amount of power stored in the power storage device 10b in the facility Hb is lower than the predicted value. Therefore, there is a possibility that power outage of the power storage device 10b may occur if it is left as it is. Therefore, at this time, the control server 100 controls the connection switching port 50 to connect the standby power storage device 20 to the connection port 40b. When the connection port 40b detects that the standby power storage device 20 is connected, the connection port 40b disconnects the connection between the power storage device 10b and the leveling control device 30 and connects the standby power storage device 20 to the leveling control device 30b. For this reason, the supply of power from the power storage device 10b is stopped and power is supplied from the standby power storage device 20 to the load of the facility Hb. As a result, power outage of the power storage device 10b can be avoided, and an increase in power consumption of the system power supply due to a shift between the actual measurement value and the predicted value of the remaining power storage amount of the power storage device 10b can be suppressed. .

  As shown in FIG. 4 (b), when the standby power storage device 20 is connected to the connection port 40b, the connection between the power storage device 10b and the leveling control device 30 is cut off. The amount (actual measured value) stops decreasing. At this time, the control server 100 causes the leveling control devices 30a to 30c to perform the overall power leveling control with the standby power storage device 20 added. Specifically, the control server 100 resets the threshold values of the leveling control devices 30a to 30c based on the respective remaining power levels of the standby power storage device 20 and the power storage devices 10a to 10c. Specifically, the control server 100 is configured such that the remaining amount of power stored in the power storage device 10a, the sum of the remaining amount of power stored in the power storage device 10b and the standby power storage device 20, and the remaining power stored in the power storage device 10c are uniform. The thresholds of the leveling control devices 30a to 30c are reset so that the remaining amount of electricity stored in the facility becomes uniform. Then, the leveling control devices 30a to 30c perform power leveling control based on the reset threshold values.

  Thereafter, it is considered that the predicted value decreases with the passage of time, and the actually measured value of the remaining amount of electricity stored in the power storage device 10b exceeds the predicted value, that is, recovers. The control server 100 shuts off the standby power storage device 20 from the connection port 40b when the remaining power storage amount (actually measured value) of the power storage device 10b exceeds the predicted value. At this time, the control server 100 causes the leveling control devices 30a to 30c to perform the overall power leveling control without the standby power storage device 20. Specifically, the control server 100 resets the threshold value of the leveling control device 30 of each facility so that the remaining power amount of the power storage devices 10a to 10c becomes uniform after the standby power storage device 20 is shut off. To do. Then, the leveling control devices 30a to 30c perform power leveling control based on the reset threshold values.

  As described above, the remaining amount of electricity stored in the electricity storage devices 10a to 10c can be held uniformly, and optimization of the overall leveling control can be achieved. Here, by performing the overall power leveling control using the standby power storage device 20, power outage can be suppressed without increasing the threshold value of the leveling device, and all the power storage devices do not have a capacity margin. The cost can be reduced.

  Next, the overall leveling control process described above will be described with reference to FIGS. FIG. 5 is an overall flowchart of the overall leveling control process, and FIG. 6 is a flowchart of the overall leveling control process when the standby power storage device is connected.

  First, the overall flow of the overall leveling control process will be described using the flowchart of FIG. In step S101, the control server 100 measures the remaining amount of power stored in the power storage device 10 in each facility. In subsequent step S102, control server 100 compares the measured value of the measured remaining power storage amount with the predicted value. Thereafter, the control server 100 proceeds to the process of step S103.

  In step S <b> 103, as a result of the comparison, the control server 100 detects the power storage device 10 in which the measured value of the remaining power storage is less than the predicted value among the power storage devices 10 in each facility. The control server 100 returns to the process of step S101 when the power storage device 10 whose actual value of the remaining power storage is less than the predicted value is not detected (step S103: No). On the other hand, when the power storage device 10 in which the measured value of the remaining power storage is less than the predicted value is detected (step S103: Yes), the control server 100 proceeds to the process of step S104.

  In step S104, control server 100 connects standby power storage device 20 to connection port 40 of power storage device 10 detected in step S103. Thereby, standby power storage device 20 is connected to leveling control device 30 to which power storage device 10 detected in step S103 was connected. In subsequent step S <b> 105, the control server 100 performs the overall leveling control process in a state where the standby power storage device 20 is added. Thereafter, the control server 100 proceeds to the process of step S106.

  In step S <b> 106, the control server 100 determines whether or not the use of the standby power storage device 20 has ended. If the control server 100 determines that the use of the spare power storage device 20 has ended (step S106: Yes), the control server 100 proceeds to the process of step S107. On the other hand, if the control server 100 determines that the use of the standby power storage device 20 has not ended (step S106: No), the control server 100 returns to the process of step S105. In step S <b> 107, the control server 100 controls the connection switching port 50 to block the standby power storage device 20 from the connection port 40. Thereafter, the control server 100 proceeds to the process of step S108.

  In step S108, the control server 100 performs overall power leveling control without a spare power storage device. That is, the control server 100 individually calculates a new threshold value for each facility so that the remaining amount of electricity stored in the power storage device 10 of each facility becomes uniform based on the remaining amount of power stored in the power storage device 10 of each facility. Then, the leveling control device 30 of each facility is set. Thereafter, the control server 100 proceeds to the process of step S109.

  In step S109, control server 100 determines whether or not spare power storage device 20 can be charged. For example, at night, the power storage device 10 of each facility is charged from the system power supply (see FIG. 3). At this time, when the remaining amount of electricity stored in the power storage device 10 of each facility is 100%, that is, when the capacity of the power storage device 10 is fully charged, the standby power storage device 20 is also charged from the system power supply via the connection port 40. It is thought that it may be allowed. Therefore, in step S109, the control server 100 determines whether or not the standby power storage device 20 can be charged based on the remaining amount of power stored in the power storage device 10 of each facility. When the control server 100 determines that the standby power storage device 20 can be charged (step S109: Yes), the control server 100 proceeds to the process of step S110, and when it determines that the standby power storage device 20 cannot be charged ( Step S109: No), this control process is returned.

  In step S <b> 110, for example, the control server 100 connects and charges the standby power storage device 20 to the connection port 40 to which the power storage device 10 that has been determined to have a remaining power storage capacity of 100%. The control server 100 returns this control process after the charging of the standby power storage device 20 is completed.

  Next, the overall leveling control in the state where the standby power storage device 20 is added in step S105 will be described with reference to FIG.

  First, in step S201, the control server 100 determines whether or not the standby power storage device 20 and the connection port 40 are connected. When determining that the auxiliary power storage device 20 and the connection port 40 are not connected (step S201: No), the control server 100 repeats the process of step S201 until it is determined that it is connected. On the other hand, if the control server 100 determines that the standby power storage device 20 and the connection port 40 are connected (step S201: Yes), the control server 100 proceeds to the process of step S202.

  In step S202, the control server 100 measures the remaining amount of power stored in the power storage device 10 and the standby power storage device 20 in each facility. In subsequent step S <b> 203, the control server 100 acquires from the information DB 110 a predicted remaining amount curve that is a graph showing a change in the predicted value of the remaining amount of power stored in the power storage device 10 of each facility. Thereafter, the control server 100 proceeds to the process of step S204.

  In step S204, the control server 100 sets a new threshold value for each facility so that the remaining amount of electricity stored in each facility becomes uniform based on the remaining amount of electricity stored in each of the power storage devices 10 and the standby power storage devices 20 of each facility. Calculate separately. Specifically, the control server 100 calculates the threshold values of the leveling control devices 30a to 30c of the facilities Ha to Hc based on the remaining power storage amounts of the standby power storage device 20 and the power storage devices 10a to 10c, respectively. To do. In subsequent step S205, control server 100 calculates a new predicted remaining amount curve for each facility based on the calculation result in step S204. Thereafter, the control server 100 proceeds to the process of step S206.

  In step S206, the control server 100 determines whether or not power failure of the power storage device 10 can be avoided based on the new predicted remaining capacity curve. If the control server 100 determines that power failure of the power storage device 10 can be avoided (step S206: Yes), the control server 100 proceeds to the process of step S207. On the other hand, if the control server 100 determines that power failure of the power storage device 10 cannot be avoided (step S206: No), the control server 100 returns to the process of step S204.

  In step S207, the control server 100 resets the new threshold value calculated in step S204 in the leveling control device 30 of each facility. As a result, the leveling control device 30 of each facility performs the overall power leveling control based on the new threshold value set for each facility. Thereafter, the control server 100 proceeds to the process of step S208.

  In step S208, the control server 100 determines whether or not the measured value of the remaining amount of electricity stored in the power storage device 10 exceeds the predicted value, that is, whether or not the remaining amount of stored electricity has recovered to the predicted value. If the control server 100 determines that the remaining amount of power stored in the power storage device 10 in each facility does not exceed the predicted value (step S208: No), the control server 100 returns to the process in step S202. On the other hand, if the control server 100 determines that the remaining amount of power stored in the power storage device 10 of each facility exceeds the predicted value (step S208: Yes), the control server 100 proceeds to the process of step S209. In step S <b> 209, the control server 100 stops the use of the standby power storage device 20 by blocking the backup power storage device 20 from the connection port 40. Thereafter, the control server 100 returns to the process of step S106 in FIG.

  As can be seen from the above description, in the power leveling system 200 according to the embodiment, the standby power storage device 20 that assists the power supply to the power storage device 10 and the threshold values of the leveling control device 30 of each facility are restored. And a control server 100 to be set. The standby power storage device 20 assists power supply to the power storage device 10 in which the measured value of the remaining power storage is lower than the predicted value. At this time, the control server 100 resets the threshold value of the leveling control device of each facility based on the respective remaining power levels of the power storage device 10 and the standby power storage device 20 of each facility. By doing in this way, it is possible to suppress the power outage without increasing the threshold of the leveling control device 30, and it is not necessary to have a capacity margin in the power storage device 10 of each facility, thereby reducing the cost. be able to.

  In the above-described embodiment, the connection port 40 has a function of shutting down the power storage device 10 from the leveling control device 30 when the standby power storage device 20 is connected. It is not limited to this. Examples of other functions of the connection port 40 are shown in FIG. FIG. 7A shows an example of the connection port 40 through which the power storage device 10 is cut off when the standby power storage device 20 is connected.

  FIG. 7B illustrates an example of the connection port 40 that combines and supplies power from both the power storage device 10 and the standby power storage device 20 to the leveling control device 30 when the standby power storage device 20 is connected. . FIG. 7C shows an example of the connection port 40 that, when the standby power storage device 20 is connected, the power from the standby power storage device 20 is supplied to the leveling control device 30 and also supplied to and charged by the power storage device 10. Is shown.

  Thus, the connection port 40 is not limited to the one having the function shown in FIG. 7A, but may have the function shown in FIG. 7B or FIG. 7C instead.

  In the power leveling system according to the above-described embodiment, only one spare power storage device 20 is provided. However, the present invention is not limited to this, and a plurality of spare power storage devices may be provided. Further, in the overall leveling control according to the above-described embodiment, the standby power storage device 20 is cut off from the leveling control device 30b when the power storage remaining amount of the power storage device 10b exceeds the predicted value. It is not limited. Instead of doing this, it goes without saying that the standby power storage device 20 may remain connected to the leveling control device 30b even when the remaining power storage amount of the power storage device 10b exceeds the predicted value. . In this case, as the threshold values of the leveling control devices 30a to 30c, the threshold values reset based on the remaining power storage amounts of the standby power storage device 20 and the power storage devices 10a to 10c are used as they are.

[Modification]
Next, a modification of the power leveling system according to the embodiment will be described. 8 and 9 are schematic diagrams illustrating an example of a modification of the power leveling system according to the embodiment.

  In the power leveling system 200 according to the above-described embodiment, the standby power storage device 20 is selectively connected to the connection port 40 of each facility by the connection switching port 50 controlled by the control server 100. It is not limited to. Instead of doing this, as shown in FIG. 8, the standby power storage device 20 may be a battery mounted on a vehicle ECA such as an electric vehicle.

  In the example shown in FIG. 8A, the control server 100 receives information on the remaining amount of power stored in the power storage device 10 of each facility, and based on the received information, the actual value of the remaining power stored in the power storage device 10 is calculated. Detect facilities below the predicted value. When the control server 100 detects that the remaining power storage amount (actually measured value) of the power storage device 10 in a certain facility (for example, “facility Hb”) is lower than the predicted value, the control server 100 detects the vehicle ECA equipped with the spare power storage device 20. Notify the detection result. When the vehicle ECA receives the detection result, the vehicle ECA heads to the facility where the measured value of the remaining power storage is lower than the predicted value, and connects the standby power storage device 20 to the connection port of the facility.

  In the example illustrated in FIG. 8B, the connection switching port 50 is provided in the parking lot, and the auxiliary power storage device 20 of the vehicle ECA parked in the parking lot is connected to the connection switching port 50. The control server 100 receives information on the remaining amount of power stored in the power storage device 10 of each facility, and detects a facility whose measured value of the remaining power stored in the power storage device 10 is lower than the predicted value based on the received information. When the control server 100 detects that the measured value of the remaining amount of power stored in the power storage device 10 of a certain facility (eg, “facility Hb”) is below the predicted value, it controls the connection switching port 50 provided in the parking lot. Then, the standby power storage device 20 is connected to a facility where the measured value of the remaining power storage is lower than the predicted value.

  In the power leveling system 200a shown in FIG. 9, the charge / discharge connection switching device 301 is provided in the parking lot, and the reserve power storage device mounted on the vehicle parked in the parking lot and the charge / discharge connection switching device 301 are provided. Connected. The charge / discharge connection switching device 301 supplies the power of the spare power storage device to the power company by reverse power flow. A charge management server 302 is installed in the electric power company. The fee management server 302 functions as a fee management device. The charge management server 302 calculates the power supplied by the reverse power flow (hereinafter referred to as “reverse power flow”). On the other hand, the control server 100 causes the facility whose actual measured value of the remaining amount of electricity stored in the power storage device 10 is lower than the predicted value to supply extra power from the system power until the actual measured value exceeds the predicted value.

  At this time, the fee management server 302 obtains the amount of power (hereinafter referred to as “auxiliary power”) that is supplied to the facility from the grid power. For example, the fee management server 302 can obtain auxiliary power supplied to each facility based on detection signals from sensors 303a to 303c that detect power consumption of a system power supply provided in each facility. The charge management server 302 calculates the power charge by regarding the calculated auxiliary power as being supplied from the standby power storage device by the amount of reverse power flow. Specifically, the charge management server 302 subtracts the power charge for the reverse power flow out of the power charge for the auxiliary power. That is, in the power leveling system 200a shown in FIG. 9, it is considered that power is supplied from the standby power storage device to the power storage device 10 of the facility via the power company.

  According to each of the above-described modifications, it is possible to suppress the power outage without increasing the threshold value of the leveling control device 30, and it is not necessary to have a capacity margin in the power storage device 10 of each facility, thereby reducing costs. can do. Further, according to each of the above-described modifications, it is possible to use existing equipment such as an electric vehicle, and it is not necessary to newly provide a spare power storage device.

  The embodiments are not limited to the above-described embodiments, and can be appropriately changed without departing from the spirit or concept of the invention that can be read from the claims and the entire specification.

Regarding the embodiment described above, the following additional notes are disclosed.
(Appendix 1)
A power leveling system comprising a leveling control device and a power storage device for leveling power consumption of a load in each of a plurality of facilities,
Among the power storage devices of the plurality of facilities, a standby power storage device that assists in power supply to a power storage device whose measured value of the remaining power storage is lower than a predicted value;
A power leveling device comprising: a control device that resets a threshold value of the leveling control device of the plurality of facilities based on the respective remaining power levels of the power storage devices of the plurality of facilities and the standby power storage device. System.
(Appendix 2)
The power leveling system according to appendix 1, wherein the control device resets the threshold value so as to level the total power consumption of the loads of the plurality of facilities as a whole.
(Appendix 3)
The control device resets the threshold value so that the remaining amount of electricity stored in each facility is uniform based on the remaining amount of electricity stored in each of the power storage devices of the plurality of facilities and the standby power storage device. The power leveling system according to attachment 2.
(Appendix 4)
A connection switching device that switches a connection between the leveling control device of the plurality of facilities and the standby power storage device;
The control device detects the power storage device by controlling the connection switching device when the power storage device of the plurality of facilities detects a power storage device whose measured value of the remaining power storage is lower than a predicted value. 4. The power leveling system according to claim 1, wherein the standby power storage device is connected to the leveling control device to which is connected.
(Appendix 5)
A charge management device for calculating an electricity charge on the assumption that the power supplied from the system power supply to the leveling control devices of the plurality of facilities is supplemented by the power supplied to the system power supply by the reverse power flow from the standby power storage device ,
The standby power storage device supplies power to the system power supply by reverse power flow,
When the control device detects a power storage device having an actual storage remaining value lower than a predicted value among the power storage devices of the plurality of facilities, the control device transmits the detected power storage device to the leveling control device to which the power storage device is connected. On the other hand, the power leveling system according to any one of appendices 1 to 3, wherein the lower power is supplied from a system power supply.

DESCRIPTION OF SYMBOLS 10 Power storage device 20 Preliminary power storage device 30 Leveling control device 40 Connection port 50 Connection switching port 100 Control server 200 Electric power leveling system

Claims (5)

A power leveling system comprising a leveling control device and a power storage device for leveling power consumption of a load in each of a plurality of facilities,
Among the power storage devices of the plurality of facilities, a standby power storage device that assists in power supply to a power storage device whose measured value of the remaining power storage is lower than a predicted value;
A power leveling device comprising: a control device that resets a threshold value of the leveling control device of the plurality of facilities based on the respective remaining power levels of the power storage devices of the plurality of facilities and the standby power storage device. System.   The power leveling system according to claim 1, wherein the control device resets the threshold value so as to level the total power consumption of loads of the plurality of facilities as a whole.   The control device resets the threshold value so that the remaining amount of electricity stored in each facility is uniform based on the remaining amount of electricity stored in each of the power storage devices of the plurality of facilities and the standby power storage device. The power leveling system according to claim 2. A connection switching device that switches a connection between the leveling control device of the plurality of facilities and the standby power storage device;
The control device detects the power storage device by controlling the connection switching device when the power storage device of the plurality of facilities detects a power storage device whose measured value of the remaining power storage is lower than a predicted value. The power leveling system according to any one of claims 1 to 3, wherein the standby power storage device is connected to the leveling control device to which is connected. A charge management device for calculating an electricity charge on the assumption that the power supplied from the system power supply to the leveling control devices of the plurality of facilities is supplemented by the power supplied to the system power supply by the reverse power flow from the standby power storage device ,
The standby power storage device supplies power to the system power supply by reverse power flow,
When the control device detects a power storage device having an actual storage remaining value lower than a predicted value among the power storage devices of the plurality of facilities, the control device transmits the detected power storage device to the leveling control device to which the power storage device is connected. In contrast, the power leveling system according to any one of claims 1 to 3, wherein the lower power is supplied from a system power supply.

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