JP6487265B2 - Power management apparatus and power management method - Google Patents

Description

  The present invention relates to a power management apparatus and a power management method for controlling a storage battery in a reverse power flow suppression state.

  2. Description of the Related Art In recent years, an energy management system (EMS: Energy Management System) that manages the power of equipment provided in a customer facility has attracted attention.

  For example, when receiving an instruction to suppress power flow from the power system (hereinafter referred to as demand response), the power management apparatus performs control for suppressing power consumption of the device, discharge control for the storage battery, and the like. Alternatively, the power management apparatus performs control (peak cut control) for suppressing the integrated value of the amount of power supplied from the power system to a predetermined value or less during a certain period (for example, 30 minutes) (for example, Patent Document 1).

JP 2012-244665 A

  Incidentally, in addition to the suppression of power flow from the power system, there may be a case where suppression of reverse power flow to the power system is required for the purpose of stabilizing the power system. Therefore, it is necessary to assume a case where both tidal current suppression and reverse tidal current suppression are required.

  However, since tidal current suppression and reverse tidal current suppression are seemingly contradictory events, sufficient studies have not been made on cases where both tidal current suppression and reverse tidal current suppression are required.

  In other words, it is not sufficient for the power management device to perform various controls considering only one of tidal current suppression and reverse power flow suppression, and it is necessary to perform various controls considering both power flow suppression and reverse power flow suppression. There is.

  Therefore, the present invention has been made to solve the above-described problems, and a power management apparatus and power that can appropriately perform various controls even when both tidal current suppression and reverse tidal current suppression are required. The purpose is to provide a management method.

  The first feature is a power management device that receives power flow suppression information indicating that power flow suppression from a power system is required in a reverse power flow suppression state where power flow suppression to the power system is required. And a control unit that switches control of the storage battery based on whether or not suppression of power flow from the power system is required in the reverse power flow suppression state.

  The second feature is a power management method that receives power flow suppression information indicating that power flow suppression from the power system is required in a reverse power flow suppression state in which reverse power flow control to the power system is required. And a step of switching the control of the storage battery based on whether or not suppression of power flow from the power system is required in the reverse power flow suppression state.

  According to the present invention, it is possible to provide a power management apparatus and a power management method capable of appropriately performing various controls even when both power flow suppression and reverse power flow suppression are required.

FIG. 1 is a diagram illustrating a power management system 1 according to the embodiment. FIG. 2 is a diagram illustrating the EMS 200 according to the embodiment. FIG. 3 is a flowchart illustrating the power management method according to the embodiment. FIG. 4 is a diagram illustrating the power management system 1 according to the first modification.

  Embodiments will be described below with reference to the drawings. In the following description of the drawings, the same or similar parts are denoted by the same or similar reference numerals.

  However, it should be noted that the drawings are schematic and ratios of dimensions may be different from actual ones. Therefore, specific dimensions and the like should be determined in consideration of the following description. Moreover, it is a matter of course that portions having different dimensional relationships and ratios are included between the drawings.

[Outline of Disclosure]
The power management device according to the summary of the disclosure is a receiving unit that receives power flow suppression information indicating that power flow suppression from the power system is requested in a reverse power flow suppression state in which power flow suppression to the power system is required And a control unit that switches control of the storage battery based on whether or not suppression of power flow from the power system is required in the reverse power flow suppression state.

  In the disclosure, the power management apparatus switches the control of the storage battery based on whether or not power flow suppression from the power system is requested in the reverse power flow suppression state. Therefore, various controls can be appropriately performed even when both the tidal current suppression and the reverse tidal current suppression are required.

[Embodiment]
(Power management system)
Hereinafter, the power management system according to the embodiment will be described. FIG. 1 is a diagram illustrating a power management system 1 according to the embodiment.

  As shown in FIG. 1, the power management system 1 includes a customer facility 100 and an external server 400. The customer facility 100 has an EMS 200, and the EMS 200 communicates with the external server 400 via the network 300.

  The customer facility 100 includes a solar battery 110, a storage battery 120, a PCS 130, a distribution board 140, and a load 150. Further, the customer facility 100 includes an EMS 200 and a remote controller 210.

  The solar cell 110 is a device that generates power in response to light reception. The solar cell 110 outputs the generated DC power. The amount of power generated by the solar cell 110 changes according to the amount of solar radiation irradiated on the solar cell 110. The solar battery 110 is an example of a distributed power source that should operate according to reverse power flow suppression information indicating that reverse power flow suppression to the power system is required.

  The storage battery 120 is a device that stores electric power. The storage battery 120 outputs the accumulated DC power. In the embodiment, the storage battery 120 may not operate according to the reverse power flow suppression information. However, it should be noted that the control of the storage battery 120 is switched based on whether or not power flow suppression from the power system is required in a reverse power flow suppression state in which reverse power flow control to the power system is required. is there.

  The PCS 130 is an example of a power converter (PCS; Power Conditioning System) that converts DC power into AC power. In the embodiment, the PCS 130 is connected to the main power line 10 </ b> L (here, the main power line 10 </ b> LA and the main power line 10 </ b> LB) connected to the power system 10, and is connected to both the solar battery 110 and the storage battery 120. The main power line 10LA is a power line that connects the power system 10 and the PCS 130, and the main power line 10LB is a power line that connects the PCS 130 and the distribution board 140.

  Here, the PCS 130 converts the DC power input from the solar battery 110 into AC power, and converts the DC power input from the storage battery 120 into AC power. Further, the PCS 130 converts AC power supplied from the power system 10 into DC power.

  Distribution board 140 is connected to main power line 10L (here main power line 10LB). Distribution board 140 branches main power line 10LB into a plurality of power lines, and distributes power to devices (here, load 150 and EMS 200) connected to the plurality of power lines.

  The load 150 is a device that consumes electric power supplied via a power line. For example, the load 150 includes devices such as a refrigerator, lighting, an air conditioner, and a television. The load 150 may be a single device or may include a plurality of devices.

  The EMS 200 is an apparatus (EMS; Energy Management System) that manages power information indicating power supplied from the power system 10 to the customer facility 100. The EMS 200 may manage the power generation amount of the solar battery 110, the charge amount of the storage battery 120, and the discharge amount of the storage battery 120. The EMS 200 is composed of, for example, a CPU or a memory. The EMS 200 may be configured integrally with the distribution board 140 or the PCS 130, or may be a cloud service via the network 300.

  In the embodiment, the EMS 200 is connected to the remote controller 210 and the network 300. For example, the EMS 200 is a power management device that switches control of the storage battery 120 based on whether or not power flow suppression from the power system is required in a reverse power flow suppression state in which reverse power flow control to the power system is required. It is an example. Whether or not power flow suppression from the power system is required is determined by power flow suppression information (demand response) indicating that power flow suppression from the power system is required.

  The remote controller 210 is attached to the PCS 130 and notifies the PCS 130 of various messages for operating the PCS 130. For example, the remote controller 210 may notify the PCS 130 of the reverse power flow suppression information and the power flow suppression information received from the EMS 200.

  The network 300 is a communication network that connects the EMS 200 and the external server 400. The network 300 may be the Internet. The network 300 may include a mobile communication network.

  The external server 400 transmits power flow suppression information indicating that power flow suppression from the power system is requested. The tidal current suppression information may include information indicating a schedule for which tidal current suppression is required. The external server 400 transmits reverse power flow suppression information indicating that reverse power flow suppression to the power system is requested. The reverse power flow suppression information may include information indicating a schedule for which reverse power flow suppression is required. That is, the external server 400 is a DR (Demand Response) server.

  Here, the tidal current suppression information includes information indicating the suppression degree of the amount of power (tidal flow rate) supplied from the power system to the customer facility 100. The suppression degree may be represented by an absolute value (for example, OO kW) of the electric energy (tidal flow rate). Alternatively, the degree of suppression may be represented by a relative value of electric energy (tidal flow rate) (for example, a decrease in OO kW). Or the suppression degree may be represented by the suppression rate (for example, (circle)%) of electric energy (tidal flow).

  Alternatively, the tidal current suppression information may include information indicating a power purchase price that is a price of tidal current from the power system. By setting a high price as the power purchase price, it is expected that the amount of power (tidal flow) supplied from the power system to the customer facility 100 will be suppressed.

  The reverse power flow suppression information includes information indicating the degree of suppression of the amount of power (reverse power flow) output from the customer facility 100 to the power system. Specifically, the reverse power flow suppression information includes information indicating the degree of suppression of the output of the distributed power source (here, the solar battery 110). The degree of suppression may be represented by an absolute value (for example, OO kW) of the output of the distributed power source (here, solar cell 110). Alternatively, the degree of suppression may be represented by a relative value (for example, a decrease in OO kW) of the output of the distributed power source (here, solar cell 110). Alternatively, the degree of suppression may be represented by an output suppression ratio (for example, OO%) of the distributed power source (here, solar cell 110). The suppression ratio is preferably a ratio with respect to an output (hereinafter referred to as “equipment certified output”) certified as an output capability of the PCS that controls the distributed power supply when the distributed power supply is installed in the customer facility 100. When the output capability of the distributed power supply and the output capability of the PCS are different, the facility certified output is the smaller output capability of these output capabilities. In the case where a plurality of PCSs are installed, the facility authorization output is the sum of the output capacities of the plurality of PCSs.

(Power management device)
The power management apparatus according to the embodiment will be described below. FIG. 2 is a diagram illustrating the EMS 200 according to the embodiment. As illustrated in FIG. 2, the EMS 200 includes a first communication unit 220, a second communication unit 230, a measurement unit 240, and a control unit 250.

  The first communication unit 220 communicates with the external server 400. For example, the 1st communication part 220 is an example of the receiving part which receives the tidal current suppression information which shows that the tidal current suppression from an electric power grid | system is requested | required. The first communication unit 220 receives reverse power flow suppression information indicating that reverse power flow suppression to the power system is requested.

  The second communication unit 230 communicates with devices (for example, the PCS 130 and the load 150) provided in the customer facility 100. For example, the second communication unit 230 transmits various control commands to the device. The second communication unit 230 receives information indicating the control state of the device from the device. In addition, the 2nd communication part 230 may communicate with the apparatus provided in the consumer facility 100 using the format based on an ECHONET Lite system.

  The measuring unit 240 is connected to a current sensor connected to a device provided in the customer facility 100, and measures the power supplied to the device and the power output from the device. For example, the measurement unit 240 measures the amount of charge of the storage battery 120, the amount of discharge of the storage battery 120, the amount of power output from the solar battery 110, the amount of power consumed by the load 150, and the like.

  The control unit 250 includes a memory and a CPU, and controls the EMS 200. Specifically, the control unit 250 controls reverse power flow to the power system according to the reverse power flow suppression information. Here, the control part 250 suppresses the output of the solar cell 110 according to the reverse power flow suppression information. The output suppression of the solar cell 110 in the reverse power flow suppression state can be performed by controlling the PCS 130, for example. The control unit 250 controls the power flow to the power system according to the power flow suppression information. For example, the control unit 250 may suppress the power consumption amount of the load 150 according to the power flow suppression information.

  In the embodiment, the control unit 250 switches the control of the storage battery 120 based on whether or not power flow suppression from the power system is required in a reverse power flow suppression state in which reverse power flow control to the power system is required. It is an example of a control part. Here, it should be noted that the reverse power flow suppression state is a state in which the output of the solar cell 110 is suppressed according to the reverse power flow suppression information.

  First, the control unit 250 controls the storage battery 120 based on at least one of a power selling price that is the price of the reverse power flow to the power system and a power purchase price that is the price of the power flow from the power system ( Cost priority control). Specifically, the control unit 250 performs discharge control of the storage battery 120 when the power selling price is higher than the power buying price in the cost priority control. On the other hand, in the cost priority control, the control unit 250 performs charge control of the storage battery 120 when the power sale price is lower than the power purchase price. The control unit 250 may perform discharge control of the storage battery 120 when the power purchase price is higher than a predetermined threshold in the cost priority control. The control unit 250 may perform charge control of the storage battery 120 when the power purchase price is lower than a predetermined threshold in the cost priority control. It is preferable that the control unit 250 controls the storage battery 120 by cost priority control when the tidal current suppression is not required in the reverse tidal current suppression state. It is preferable that the control unit 250 controls the storage battery 120 by cost priority control when there is no plan to request power flow suppression in the reverse power flow suppression state.

  Secondly, the control unit 250 gives priority to the discharge control of the storage battery 120 when the power flow suppression is requested in the reverse power flow suppression state (discharge priority control). Specifically, in the discharge priority control, the control unit 250 causes the amount of power output from a distributed power source other than the storage battery 120 (here, the solar battery 110) and the discharge amount of the storage battery 120 to exceed the power consumption of the load 150. In addition, it is preferable to perform discharge control of the storage battery 120.

  Here, it should be noted that the discharge priority control only needs to give priority to the discharge control of the storage battery 120 as compared with the cost priority control described above. For example, the control unit 250 may facilitate the discharge control of the storage battery 120 by adding an offset (a value greater than 0) to the power sale price in the comparison between the power sale price and the power purchase price. . Or the control part 250 may make discharge control of the storage battery 120 easy to be performed by subtracting an offset (value larger than 0) from the power purchase price in the comparison between the power sale price and the power purchase price. . Or the control part 250 may make discharge control of the storage battery 120 easy to be performed by using a threshold value smaller than the threshold value used by cost priority control as a predetermined threshold value which should be compared with a power purchase price.

  However, the control part 250 does not need to perform discharge control of the storage battery 120 in discharge priority control, when the storage amount of the storage battery 120 is less than a predetermined threshold value. In such a case, the control unit 250 may not perform charge control of at least the storage battery 120 and maintains the output of the storage battery 120 at zero.

  For example, the predetermined threshold value to be compared with the storage amount of the storage battery 120 may be determined according to the storage amount to be secured in the power failure period. Alternatively, the predetermined threshold value to be compared with the amount of power stored in the storage battery 120 may be determined according to a future power purchase price schedule or a future power consumption schedule of the load 150. Specifically, when the power purchase price increases in the future, it is unfavorable to perform charge control of the storage battery 120 in a time zone in which the power purchase price is high, so a large threshold is set as the predetermined threshold. When the power consumption of the load 150 increases in the future, it is advantageous to maintain the amount of power stored in the storage battery 120, so a large threshold is set as the predetermined threshold. Alternatively, the predetermined threshold to be compared with the amount of power stored in the storage battery 120 may be a fixed value.

  Thirdly, the control unit 250 prioritizes charging control of the storage battery 120 when charging suppression is scheduled to be requested in the reverse flow suppressing state (charging priority control).

  Here, it should be noted that the charge priority control only needs to give priority to the charge control of the storage battery 120 as compared to the cost priority control described above. For example, the control unit 250 may make charge control of the storage battery 120 easier to perform by subtracting an offset (a value greater than 0) from the power sale price in the comparison between the power sale price and the power purchase price. . Alternatively, the control unit 250 may make charge control of the storage battery 120 easier to perform by adding an offset (a value greater than 0) to the power purchase price in the comparison between the power sale price and the power purchase price. . Or the control part 250 may make it easy to perform charge control of the storage battery 120 by using a threshold value larger than the threshold value used by cost priority control as a predetermined threshold value which should be compared with a power purchase price.

  However, the control part 250 does not need to perform charge control of the storage battery 120 in charge priority control, when the storage amount of the storage battery 120 exceeds the predetermined threshold value. In such a case, the control unit 250 does not need to perform at least discharge control of the storage battery 120, and maintains the output of the storage battery 120 at zero.

  For example, the predetermined threshold value to be compared with the amount of power stored in the storage battery 120 may be determined according to a future power purchase price schedule or a future power consumption schedule of the load 150. Specifically, when the power purchase price is lowered in the future, it is advantageous to perform charging control of the storage battery 120 in a time zone when the power purchase price is low, and therefore a small threshold is set as the predetermined threshold. When the power consumption of the load 150 increases in the future, it is advantageous to increase the amount of power stored in the storage battery 120, and thus a large threshold is set as the predetermined threshold. Alternatively, the predetermined threshold to be compared with the amount of power stored in the storage battery 120 may be a fixed value.

(Power management method)
Hereinafter, a power management method according to the embodiment will be described. FIG. 3 is a flowchart illustrating the power management method according to the embodiment.

  As shown in FIG. 3, in step S10, the EMS 200 (control unit 250) determines whether or not the current state is a reverse power flow suppression state. If the determination result is YES, the EMS 200 performs the process of step S11. If the determination result is NO, the EMS 200 performs the process of step S15.

  In step S11, the EMS 200 (control unit 250) determines whether or not tidal current suppression is requested. If the determination result is YES, the EMS 200 performs the process of step S13. If the determination result is NO, the EMS 200 performs the process of step S12.

  In step S12, the EMS 200 (control unit 250) determines whether or not there is a plan to request tidal current suppression. If the determination result is YES, the EMS 200 performs the process of step S14. If the determination result is NO, the EMS 200 performs the process of step S15.

  In step S13, the EMS 200 (control unit 250) performs the discharge priority control described above. It should be noted that the discharge priority control only needs to give priority to the discharge control of the storage battery 120 as compared with the cost priority control described above.

  In step S14, the EMS 200 (control unit 250) performs the charge priority control described above. It should be noted that the charge priority control only needs to give priority to the charge control of the storage battery 120 as compared with the cost priority control described above.

  In step S15, the EMS 200 (control unit 250) performs the above-described cost priority control. The EMS 200 controls the storage battery 120 based on at least one of a power sale price and a power purchase price.

(Function and effect)
The EMS 200 (power management device) switches the control of the storage battery based on whether or not power flow suppression from the power system is requested in the reverse power flow suppression state. Therefore, various controls can be appropriately performed even when both the tidal current suppression and the reverse tidal current suppression are required.

  In addition, when both the tidal current suppression and the reverse tidal current suppression are required, the storage battery 120 is controlled with priority given to the reverse tidal current suppression over the tidal current suppression, so that power management can be performed efficiently. Further, when the suppression of reverse power flow is a more urgent request than the control of power flow, by performing such control in a plurality of customer facilities 100, the electric power company can stabilize the power system in a short period of time. Can be realized.

[Modification 1]
Hereinafter, Modification Example 1 of the embodiment will be described. In the following, differences from the embodiment will be mainly described.

  In the first modification, as shown in FIG. 4, the customer facility 100 includes a smart meter 160 in addition to the configuration shown in FIG. 1. The smart meter 160 measures the amount of power flow from the power system (power purchased). The smart meter 160 may measure the amount of reverse power flow to the power system (the amount of power sold).

  Here, the smart meter 160 communicates with the external server 400. For example, the smart meter 160 receives power flow suppression information indicating that power flow suppression from the power system is requested. The smart meter 160 receives reverse power flow suppression information indicating that reverse power flow suppression to the power system is requested.

  In such a case, the EMS 200 (first communication unit 220) communicates with the smart meter 160. The EMS 200 (first communication unit 220) receives the power flow suppression information and the reverse power flow suppression information from the smart meter 160. The EMS 200 (first communication unit 220) may receive the power purchase price and the power sale price described above from the smart meter 160.

[Other Embodiments]
Although the present invention has been described with reference to the above-described embodiments, it should not be understood that the descriptions and drawings constituting a part of this disclosure limit the present invention. From this disclosure, various alternative embodiments, examples and operational techniques will be apparent to those skilled in the art.

  In the embodiment, a case has been described in which the power management device that switches the control of the storage battery 120 is the EMS 200 based on whether or not power flow suppression from the power system is requested in the reverse power flow suppression state. However, the embodiment is not limited to this. The power management apparatus may be the PCS 130 described above.

  The PCS 130 may be connected to a power generator such as a fuel cell. In the embodiment, the case where the output of the solar cell 110 is suppressed has been described. However, the embodiment may be applied to the case where the output of the storage battery 120 and the power generation device connected to the PCS 130 is suppressed. When the output of the storage battery 120 and the power generation device is suppressed, the output may be adjusted by controlling the PCS 130, or the output may be adjusted by controlling the storage battery 120 and the power generation device. By directly controlling the storage battery 120 and the power generation device, power loss can be reduced.

  DESCRIPTION OF SYMBOLS 1 ... Power management system, 10 ... Power system, 10L ... Main power line, 100 ... Consumer facility, 110 ... Solar cell, 120 ... Storage battery, 130 ... PCS, 140 ... Distribution board, 150 ... Load, 160 ... Smart meter, 200 ... EMS, 210 ... Remote controller, 220 ... First communication unit, 230 ... Second communication unit, 240 ... Measurement unit, 250 ... Control unit, 300 ... Network, 400 ... External server

Claims (7)

A receiving unit that receives power flow suppression information indicating that power flow suppression from the power system is required in a reverse power flow suppression state in which power flow suppression to the power system is required;
A power management device comprising: a control unit that switches control of the storage battery based on whether or not power flow suppression from the power system is requested in the reverse power flow suppression state.   2. The power management apparatus according to claim 1, wherein the control unit prioritizes discharge control of the storage battery when the power flow suppression is requested in the reverse power flow suppression state.   In the reverse power flow suppression state, the control unit is configured so that the amount of power output from a distributed power source other than the storage battery and the discharge amount of the storage battery exceed the power consumption of the load when the power flow suppression is requested. The power management apparatus according to claim 2, wherein discharge control of the storage battery is performed. The tidal current suppression information includes information indicating a schedule for which the tidal current suppression is required,
The said control part gives priority to charge control of the said storage battery, when there exists a plan where the said tidal current suppression is requested | required in the said reverse tidal current suppression state. Power management device.   The control unit, in the reverse power flow suppression state, when the power flow suppression is not required, the power selling price that is the price of the reverse power flow to the power system and the power purchase price that is the price of the power flow from the power system The power management apparatus according to any one of claims 1 to 4, wherein the storage battery is controlled based on at least one of them.   The control unit, in the reverse power flow suppression state, when there is no plan to require the flow control, the power selling price that is the price of the reverse power flow to the power system and the power purchase that is the price of the power flow from the power system The power management apparatus according to any one of claims 1 to 4, wherein the storage battery is controlled based on at least one of prices. Receiving a power flow suppression information indicating that a power flow suppression from the power system is required in a reverse power flow suppression state in which a reverse power flow suppression to the power system is required;
And a step of switching the control of the storage battery based on whether or not power flow suppression from the power system is required in the reverse power flow suppression state.

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