JP2018117508A - Power supply control method and controller - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a power supply control method and controller, capable of approximately keeping an inverse load flow amount from a storage battery device to a power system.SOLUTION: The power supply control method includes a step A for controlling a storage battery device and a step B for controlling a dispersed power supply allowing an inverse load flow to a power system. The step A includes a step for controlling the storage battery device on the basis of a condition showing whether or not an inverse load flow from the storage battery device to the power system is allowed and a condition showing whether or not an assist of an inverse load flow from the dispersed power supply to the power system is allowed for the storage battery device.SELECTED DRAWING: Figure 6

Description

  The present invention relates to a power supply control method and a control device.

  2. Description of the Related Art In recent years, in order to maintain the power supply / demand balance of a power system, a technique for suppressing a tidal flow from the power system to the facility or a reverse flow from the facility to the power system is known (for example, Patent Documents 1 and 2). . Specifically, the tidal flow rate or the reverse tidal flow rate is suppressed by transmitting a control message from the power management server to the control device.

JP 2013-169104 A JP 2014-128107 A

  By the way, in recent years, in the case where the solar cell device and the storage battery device coexist, in addition to the reverse flow from the solar cell device to the power system, studies have been started on the amount of reverse tide from the storage battery device to the power system. Under such a background, it is necessary to consider various matters in order to appropriately perform the reverse tide amount from the storage battery device to the power system.

  Accordingly, the present invention has been made to solve the above-described problems, and provides a power supply control method and a control device that can appropriately perform the reverse tide amount from the storage battery device to the power system. Objective.

  The power control method according to the first feature includes a step A for controlling the storage battery device and a step B for controlling a distributed power source that allows reverse power flow to the power system. The step A includes a condition indicating whether or not reverse power flow from the storage battery device to the power system is permitted, and whether or not the storage battery device is allowed to assist reverse power flow from the distributed power source to the power system. And a step of controlling the storage battery device based on a condition indicating the above.

  The control device according to the second feature includes a control unit that controls a distributed power source that allows reverse power flow to the storage battery device and the power system. The control unit determines whether or not reverse power flow from the storage battery device to the power system is allowed and whether or not the storage battery device is allowed to assist reverse power flow from the distributed power source to the power system. The storage battery device is controlled based on a condition indicating the above.

  According to one aspect, it is possible to provide a power supply control method and a control device capable of appropriately performing the amount of reverse tide from the storage battery device to the power system.

FIG. 1 is a diagram illustrating a power supply control system 100 according to the embodiment. FIG. 2 is a diagram illustrating a facility 300 according to the embodiment. FIG. 3 is a diagram illustrating the power management server 200 according to the embodiment. FIG. 4 is a diagram illustrating the local control device 360 according to the embodiment. FIG. 5 is a diagram illustrating a power generation time zone of the distributed power supply according to the embodiment. FIG. 6 is a diagram illustrating a list of power supply control methods according to the embodiment. FIG. 7 is a diagram illustrating a power control method according to the embodiment. FIG. 8 is a diagram illustrating a power control method according to the embodiment. FIG. 9 is a diagram illustrating a power control method according to the embodiment. FIG. 10 is a diagram illustrating a power control method according to the embodiment. FIG. 11 is a diagram illustrating a power control method according to the embodiment.

  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 or ratios are included between the drawings.

[Embodiment]
(Power control system)
Hereinafter, a power supply control system according to the embodiment will be described.

  As shown in FIG. 1, the power supply control system 100 includes a power management server 200, a facility 300, and a power company 400. In FIG. 1, facilities 300 </ b> A to 300 </ b> C are illustrated as the facility 300.

  Each facility 300 is connected to the power system 110. In the following, the flow of power from the power system 110 to the facility 300 is referred to as tidal current, and the flow of power from the facility 300 to the power system 110 is referred to as reverse power flow.

  The power management server 200, the facility 300, and the power company 400 are connected to the network 120. The network 120 may provide a line between the power management server 200 and the facility 300 and a line between the power management server 200 and the power company 400. The network 120 is, for example, the Internet. The network 120 may provide a dedicated line such as a VPN (Virtual Private Network).

  The power management server 200 is a server managed by a business operator such as a power generation business, a power transmission / distribution business, or a retail business.

  The power management server 200 transmits a control message instructing control of a distributed power source (for example, the solar cell device 310 or the storage battery device 320) provided in the facility 300 to the local control device 360 provided in the facility 300. For example, the power management server 200 may transmit a power flow control message (for example, DR; Demand Response) that requests control of power flow, or may transmit a reverse power flow control message that requests control of reverse power flow. Furthermore, the power management server 200 may transmit a power control message for controlling the operating state of the distributed power. The degree of control of the tidal current or the reverse tidal current may be represented by an absolute value (for example, OO kW) or a relative value (for example, OO%). Or the control degree of a tidal current or a reverse tidal current may be represented by two or more levels. The degree of control of power flow or reverse power flow may be represented by a power rate (RTP; Real Time Pricing) determined by the current power supply / demand balance, or a power rate (TOU; Time Of Use) determined by a past power supply / demand balance. May be represented by

  As shown in FIG. 2, the facility 300 includes a solar cell device 310, a storage battery device 320, a load device 330, a wattmeter 340, a wattmeter 350, and a local control device 360.

  The solar cell device 310 is a distributed power source that generates power in response to light such as sunlight. The solar cell device 310 is an example of a distributed power source in which reverse power flow to the power system 110 is permitted. The solar cell device 310 includes, for example, a PCS (Power Conditioning System) and a solar panel.

  The storage battery device 320 is a distributed power source that performs power charging and power discharging. The storage battery device 320 is an example of a distributed power source in which reverse power flow to the power system 110 is permitted. The storage battery device 320 includes, for example, a PCS and a storage battery cell. The solar cell device 310 and the storage battery device 320 may be a power source used for VPP (Virtual Power Plant).

  The load device 330 is a device that consumes power. The load device 330 is, for example, an air conditioning device, a lighting device, an AV (Audio Visual) device, or the like.

  The wattmeter 340 measures the amount of power flow from the power system 110 to the facility 300 and the amount of reverse power flow from the facility 300 to the power system 110. The power meter 340 is a smart meter belonging to the power company 400, for example.

  The wattmeter 350 measures the amount of power generated by the solar cell device 310. The wattmeter 350 is, for example, a meter with a certification certified by a third party.

  The local control device 360 is a device (EMS; Energy Management System) for managing the power of the facility 300. The local control device 360 may control the operation state of the solar cell device 310 or may control the operation state of the storage battery device 320 provided in the facility 300. Details of the local control device 360 will be described later (see FIG. 4).

  In the embodiment, communication between the power management server 200 and the local control device 360 is performed according to the first protocol. On the other hand, communication between the local control device 360 and the distributed power supply (solar cell device 310 or storage battery device 320) is performed according to a second protocol different from the first protocol. As the first protocol, for example, a protocol compliant with Open ADR (Automated Demand Response) or a unique dedicated protocol can be used. As the second protocol, for example, a protocol conforming to ECHONET Lite, SEP (Smart Energy Profile) 2.0, KNX, or an original dedicated protocol can be used. Note that the first protocol and the second protocol only need to be different. For example, even if both are unique dedicated protocols, they may be protocols created according to different rules.

  The electric power company 400 is an entity that provides an infrastructure such as the electric power system 110, and is, for example, a power generation company. The electric power company 400 may entrust various operations to a business such as a power transmission / distribution business or a retail business.

(Power management server)
Hereinafter, the power management server according to the embodiment will be described. As illustrated in FIG. 3, the power management server 200 includes a management unit 210, a communication unit 220, and a control unit 230. The power management server 200 is an example of a VTN (Virtual Top Node).

  The management unit 210 is configured by a storage medium such as a non-volatile memory and / or an HDD, and manages data regarding the facility 300. The data regarding the facility 300 includes, for example, the type of the distributed power source (solar cell device 310 or storage battery device 320) provided in the facility 300, the specifications of the distributed power source (solar cell device 310 or storage battery device 320) provided in the facility 300, and the like. . The spec may be the rated generated power of the solar cell device 310, the rated output power of the storage battery device 320, or the like.

  The communication unit 220 includes a communication module, and communicates with the local control device 360 via the network 120. As described above, the communication unit 220 performs communication according to the first protocol. For example, the communication unit 220 transmits the first message to the local control device 360 according to the first protocol. The communication unit 220 receives the first message response from the local control device 360 according to the first protocol.

  The control unit 230 includes a memory, a CPU, and the like, and controls each component provided in the power management server 200. For example, the control unit 230 instructs the local control device 360 provided in the facility 300 to control the distributed power source (the solar cell device 310 or the storage battery device 320) provided in the facility 300 by transmitting a control message. As described above, the control message may be a power flow control message, a reverse power flow control message, or a power control message.

(Local control device)
Hereinafter, a local control device according to the embodiment will be described. As illustrated in FIG. 4, the local control device 360 includes a first communication unit 361, a second communication unit 362, and a control unit 363. The local control device 360 is an example of a VEN (Virtual End Node).

  The first communication unit 361 includes a communication module, and communicates with the power management server 200 via the network 120. As described above, the first communication unit 361 performs communication according to the first protocol. For example, the first communication unit 361 receives the first message from the power management server 200 according to the first protocol. The first communication unit 361 transmits a first message response to the power management server 200 according to the first protocol.

  The 2nd communication part 362 is comprised by the communication module, and communicates with a distributed power supply (solar cell apparatus 310 or the storage battery apparatus 320). As described above, the second communication unit 362 performs communication according to the second protocol. For example, the second communication unit 362 transmits the second message to the distributed power source according to the second protocol. The second communication unit 362 receives the second message response from the distributed power source according to the second protocol.

  The control unit 363 is configured by a memory, a CPU, and the like, and controls each component provided in the local control device 360. Specifically, in order to control the power of the facility 300, the control unit 363 instructs the device to set the operating state of the distributed power supply by transmitting the second message and receiving the second message response. In order to manage the power of the facility 300, the control unit 363 may instruct the distributed power supply to report information on the distributed power supply by transmitting the second message and receiving the second message response.

  In the embodiment, the control unit 363 provides the storage battery device 320 with a condition indicating whether or not reverse power flow from the storage battery device 320 to the power system 110 is permitted and for assisting reverse power flow from the solar cell device 310 to the power system 110. The storage battery device 320 is controlled based on a condition indicating whether or not it is permitted.

  For example, when the reverse power flow from the storage battery device 320 to the power system 110 is allowed, the control unit 363 does not depend on the power consumption amount of the load device 330 during the non-power generation time other than the power generation time of the solar cell device 310. In addition, control may be performed to allow the storage battery device 320 to perform a discharging operation. Such a discharge operation may be an operation of discharging a constant power (rated power). Control unit 363 may instruct standby operation or charging operation of storage battery device 320 during non-power generation time other than power generation time of solar cell device 310.

  When the reverse power flow from the storage battery device 320 to the power system 110 is not allowed, the control unit 363 does not exceed the power consumption amount of the load device 330 in the non-power generation time other than the power generation time of the solar cell device 310. You may perform control which accept | permits that the storage battery apparatus 320 performs discharge operation. Such a discharge operation may be an operation of discharging so as to follow the power consumption of the load device 330. That is, the control unit 363 may perform control to suppress the discharging operation of the storage battery device 320 that exceeds the power consumption amount of the load device 330 during the non-power generation time other than the power generation time of the solar cell device 310. Control unit 363 may instruct standby operation or charging operation of storage battery device 320 during non-power generation time other than power generation time of solar cell device 310.

  The control unit 363 allows the reverse power flow from the storage battery device 320 to the power system 110 and allows the storage battery device 320 to assist the reverse power flow from the solar cell device 310 to the power system 110. Control that allows the storage battery device 320 to perform a discharge operation may be performed during the power generation time of the solar cell device 310 regardless of the power consumption of the load device 330. Such a discharge operation may be an operation of discharging a constant power (rated power). The control unit 363 may instruct the standby operation or the charging operation of the storage battery device 320 during the power generation time of the solar cell device 310.

  The control unit 363 allows the storage battery device 320 to assist reverse power flow from the solar cell device 310 to the power system 110, and when the generated power amount of the solar cell device 310 is greater than or equal to the power consumption amount of the load device 330. In the power generation time of the solar battery device 310, control may be performed that allows the storage battery device 320 to perform a discharge operation within a range that does not exceed the power consumption of the load device 330. Such a discharge operation may be an operation of discharging so as to follow the power consumption of the load device 330. Such a discharge operation may be an operation of discharging so as to follow the power consumption of the load device 330. That is, the control unit 363 performs control to suppress the discharging operation of the storage battery device 320 that exceeds the power consumption amount of the load device 330 when the power generation amount of the solar cell device 310 is equal to or greater than the power consumption amount of the load device 330. Just do it. The control unit 363 may instruct a standby operation or a charging operation of the storage battery device 320 when the generated power amount of the solar cell device 310 is equal to or greater than the power consumption amount of the load device 330.

  The control unit 363 does not allow the storage battery device 320 to assist reverse power flow from the solar cell device 310 to the power system 110, and the generated power amount of the solar cell device 310 is equal to or greater than the power consumption amount of the load device 330. Moreover, you may perform control which suppresses the discharge operation of the storage battery apparatus 320 in the electric power generation time of the solar cell apparatus 310. FIG. Such control for suppressing the discharge operation may be control that does not perform the discharge operation, and may be control for stopping the discharge operation, for example. The control unit 363 may instruct a standby operation or a charging operation of the storage battery device 320 when the generated power amount of the solar cell device 310 is equal to or greater than the power consumption amount of the load device 330.

  The control unit 363 allows the storage battery device 320 to assist the reverse power flow from the solar cell device 310 to the power system 110, and when the generated power amount of the solar cell device 310 is smaller than the power consumption amount of the load device 330. In the power generation time of the solar cell device 310, control may be performed that allows the discharge operation of the storage battery device 320 within a range that does not exceed the power consumption of the load device 330. Such a discharge operation may be an operation of discharging so as to follow the power consumption of the load device 330. That is, the control unit 363 performs control to suppress the discharging operation of the storage battery device 320 exceeding the power consumption amount of the load device 330 when the power generation amount of the solar cell device 310 is smaller than the power consumption amount of the load device 330. Just do it. The control unit 363 may instruct a standby operation or a charging operation of the storage battery device 320 when the generated power amount of the solar cell device 310 is smaller than the power consumption amount of the load device 330.

  When the storage battery device 320 does not allow the storage battery device 320 to assist the reverse power flow from the solar cell device 310 to the power system 110, the control unit 363 has a smaller amount of power generated by the solar cell device 310 than the power consumption amount of the load device 330. In addition, during the power generation time of the solar cell device 310, control is performed to allow the discharge operation of the storage battery device 320 within a range that does not exceed the power amount obtained by removing the power generation amount of the solar cell device 310 from the power consumption amount of the load device 330. Also good. That is, when the generated power amount of the solar cell device 310 is smaller than the consumed power amount of the load device 330, the control unit 363 removes the generated power amount of the solar cell device 310 from the consumed power amount of the load device 330. Control that suppresses the discharge operation of the storage battery device 320 exceeding the limit may be performed. The control unit 363 may instruct a standby operation or a charging operation of the storage battery device 320 when the generated power amount of the solar cell device 310 is smaller than the power consumption amount of the load device 330.

(Power generation time)
Hereinafter, an example of the power generation time according to the embodiment will be described. The power generation time is the time during which the solar cell device 310 is generating power.

  As shown in FIG. 5, the start time of the power generation time is the time when the solar cell device 310 starts power generation, and may be, for example, the sunrise time. Similarly, the end time of the power generation time is the time when the solar cell device 310 ends the power generation, and may be, for example, the sunset time. The start time of the power generation time may be the same time as the sunrise time or may be a time before the sunrise time. Similarly, the end time of the power generation time may be the same time as the sunset time, or may be a time after the sunset time.

  For example, as shown in the figure, consider a facility 300 in which the power demand peaks twice in the morning and at night. Hereinafter, the non-power generation time other than the power generation time of the solar cell device 310 is referred to as a first time. Of the power generation time of the solar cell device 310, the time when the power generation amount of the solar cell device 310 is smaller than the power consumption amount of the load device 330 is referred to as second time, and the power generation amount of the solar cell device 310 is The time that is equal to or greater than the power consumption is referred to as the third time.

  FIG. 5 illustrates a case where the time from the sunrise time to the sunset time is the power generation time for simplification of description. However, the embodiment is not limited to this.

  The power generation time may be a time during which the solar cell device 310 generates power, and may be specified with a time width in which the solar cell device 310 can detect power generation as a minimum unit. In other words, a plurality of power generation times may occur between the sunrise time and the sunset time. Similarly, the non-power generation time may be a time when the solar cell device 310 is not generating power, and may be specified with a time width in which the solar cell device 310 can detect non-power generation as a minimum unit. One or more non-power generation times may occur between the sunrise time and the sunset time. Furthermore, the number of occurrences and the order of occurrence of the second time and the third time are arbitrary between the sunrise time and the sunset time.

  In such a case, as shown in FIG. 6, the discharge amount (BAT discharge amount) of the storage battery device 320 indicates whether or not reverse power flow (BAT reverse power flow) from the storage battery device 320 to the power system 110 is permitted. Control is performed according to the conditions shown and whether the storage battery device 320 is allowed to assist reverse power flow (BAT assistance) from the solar cell device 310 to the power system 110.

  In FIG. 6, the first control is control that allows the discharge operation of the storage battery device 320 within a range that does not exceed the power consumption of the load device 330. In the first control, standby operation or charging operation of the storage battery device 320 may be allowed.

  The second control is control that allows the storage battery device 320 to perform a discharge operation regardless of the power consumption of the load device 330. Such a discharge operation may be an operation of discharging a constant power (rated power). In the second control, the standby operation or the charging operation of the storage battery device 320 may be allowed.

  The third control is a control that allows the discharge operation of the storage battery device 320 within a range that does not exceed the amount of power obtained by removing the amount of power generated by the solar cell device 310 (PV power generation amount) from the amount of power consumed by the load device 330. In the third control, standby operation or charging operation of the storage battery device 320 may be allowed.

  The fourth control is control that allows the discharge operation of the storage battery device 320 within a range that does not exceed the power consumption of the load device 330. According to such a discharge operation, reverse power flow from the facility 300 to the power system 110 is promoted within a range not exceeding the amount of power generated by the solar cell device 310 (so-called push-up control).

  The fifth control is a control that suppresses the discharging operation of the storage battery device 320. In the fifth control, the standby operation or the charging operation of the storage battery device 320 may be allowed.

  The sixth control is control that allows the discharge operation of the storage battery device 320 within a range that does not exceed the power consumption of the load device 330. According to such a discharge operation, the reverse power flow from the facility 300 to the power system 110 increases (so-called push-up control) within a range that does not exceed the amount of power generated by the solar cell device 310.

  Here, no. 1 and no. According to the control 3, since there is no reverse power flow of the power output from the storage battery device 320, the power sale price (PV) of the solar cell device 310 can be used as the power sale price. Furthermore, no. According to the control of No. 3, since the power output from the storage battery device 320 and the generated power of the solar cell device 310 are not mixed as a reverse power flow from the facility 300 to the power system 110, the selling price is appropriately managed. can do.

  No. 2 and no. According to the control 4, a power selling price (W power generation) applied to so-called push-up control can be used as the power selling price. Furthermore, no. 4, there is a possibility that the power output from the storage battery device 320 and the generated power of the solar cell device 310 may be mixed as a reverse power flow from the facility 300 to the power system 110, but the power selling price (W power generation) ) Is applied uniformly, no. As with the control 2, it is easy to manage the power selling price. No. The power selling price applied in the control of No. 4 is No. It may be the same as the power selling price applied in the control of No. 2. No. The power selling price applied in the control of No. 4 is No. It may be different from the power selling price applied in the control of No. 2.

  No. According to the control 5, a power selling price (W power generation) applied to so-called push-up control can be used. No. The power selling price applied in the control of No. 5 is No. 2 control or No. 2 control. It may be the same as the power selling price applied in the control of No. 4. No. The power selling price applied in the control of No. 5 is No. 2 control or No. 2 control. It may be different from the power selling price applied in the control of No. 4. No. According to the control of No. 5, no. 4, the storage battery device 320 is not discharged until the amount of power generated by the solar cell device 310 is exceeded in the second time and the third time. Therefore, no. No. 2 is the same as the power selling price applied in the control of No. 2. Even when applied to the control of No. 5, 5 and No. 5 control. The unfair feeling between the two controls is reduced.

(Power control method)
Hereinafter, a power control method according to the embodiment will be described.

  First, No. 1 shown in FIG. 1 will be described with reference to FIG. As illustrated in FIG. 7, in step S10, the local control device 360 determines whether or not the current state corresponds to the first time. If the determination result is YES, the process of step S12 is performed, and if the determination result is NO, the process of step S11 is performed.

  In step S11, the local control device 360 determines whether or not the current state corresponds to the second time. If the determination result is YES, the process of step S13 is performed. If the determination result is NO, the process of step S14 is performed.

  In step S12, the local control device 360 controls the storage battery device 320 according to the first control described above.

  In step S13, the local control device 360 controls the storage battery device 320 according to the third control described above.

  In step S14, the local control device 360 controls the storage battery device 320 according to the fifth control described above.

  Second, No. 1 shown in FIG. The second control will be described with reference to FIG. As shown in FIG. 8, in step S20, the local control device 360 determines whether or not the current state corresponds to the first time. If the determination result is YES, the process of step S22 is performed, and if the determination result is NO, the process of step S21 is performed.

  In step S21, the local control device 360 determines whether or not the current state corresponds to the second time. If the determination result is YES, the process of step S23 is performed, and if the determination result is NO, the process of step S24 is performed.

  In step S22, the local control device 360 controls the storage battery device 320 according to the first control described above.

  In step S23, the local control device 360 controls the storage battery device 320 according to the fourth control described above.

  In step S24, the local control device 360 controls the storage battery device 320 according to the sixth control described above.

  Third, No. 1 shown in FIG. 3 will be described with reference to FIG. As shown in FIG. 9, in step S30, the local control device 360 determines whether or not the current state corresponds to the first time. If the determination result is YES, the process of step S32 is performed, and if the determination result is NO, the process of step S31 is performed.

  In step S31, the local control device 360 determines whether or not the current state corresponds to the second time. If the determination result is YES, the process of step S33 is performed, and if the determination result is NO, the process of step S34 is performed.

  In step S32, the local control device 360 controls the storage battery device 320 according to the second control described above.

  In step S33, the local control device 360 controls the storage battery device 320 according to the third control described above.

  In step S34, the local control device 360 controls the storage battery device 320 according to the above-described fifth control.

  Fourth, No. 1 shown in FIG. 4 will be described with reference to FIG. As shown in FIG. 10, in step S40, the local control device 360 determines whether or not the current state corresponds to the first time. If the determination result is YES, the process of step S42 is performed. If the determination result is NO, the process of step S41 is performed.

  In step S41, the local control device 360 determines whether or not the current state corresponds to the second time. If the determination result is YES, the process of step S43 is performed. If the determination result is NO, the process of step S44 is performed.

  In step S42, the local control device 360 controls the storage battery device 320 according to the second control described above.

  In step S43, the local control device 360 controls the storage battery device 320 according to the second control described above.

  In step S44, the local control device 360 controls the storage battery device 320 according to the second control described above.

  That is, no. In the control 4, the second control is applied regardless of the current state.

  Fifth, No. 1 shown in FIG. 5 will be described with reference to FIG. As shown in FIG. 11, in step S50, the local control device 360 determines whether or not the current state corresponds to the first time. If the determination result is YES, the process of step S52 is performed. If the determination result is NO, the process of step S51 is performed.

  In step S51, the local control device 360 determines whether or not the current state corresponds to the second time. If the determination result is YES, the process of step S53 is performed, and if the determination result is NO, the process of step S54 is performed.

  In step S52, the local control device 360 controls the storage battery device 320 according to the second control described above.

  In step S53, the local control device 360 controls the storage battery device 320 according to the fourth control described above.

  In step S54, the local control device 360 controls the storage battery device 320 according to the sixth control described above.

(Function and effect)
In the embodiment, the local control device 360 is provided with a condition indicating whether or not reverse power flow from the storage battery device 320 to the power system 110 is permitted, and assisting reverse power flow from the solar cell device 310 to the power system 110. The storage battery device 320 is controlled based on a condition indicating whether or not the battery is allowed. The reverse tide amount from the storage battery device 320 to the power system 110 can be performed while applying an appropriate power selling price.

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

  In the first modification, at least one of the allowable reverse power flow time in which the reverse power flow from the storage battery device 320 is allowed and the non-reverse power flow allowable time in which the reverse power flow from the storage battery device 320 is not allowed are the storage battery device 320 and the solar battery. The power management server 200 that manages the local control device 360 provided in the facility 300 including the device 310 may be designated. Such designation may be performed by transmitting a control message from the power management server 200 to the local control device 360.

  At least one of the allowable reverse power flow time and the allowable non-reverse power flow time may be set in the local control device 360. The setting of at least one of the allowable reverse power flow time and the allowable non-reverse power flow time in the local control device 360 may be performed by an operator before shipment from the factory, or may be performed by an operator after shipment from the factory. Such setting may not be arbitrarily performed by the user of the facility 300.

  For example, as shown in FIG. In the control 3, the allowable backward flow time includes at least a first time (non-power generation time). Here, when the execution of the above-described third control is ensured, the allowable reverse power flow time may include the second time. Similarly. When the execution of the above-described fifth control is ensured, the allowable reverse power flow time may include the third time. In such a case, the non-reverse power flow allowable time is a time (power generation time) excluding at least the first time. When the execution of the third control described above is not ensured, the non-reverse flow allowable time may include the second time. Similarly, when the execution of the fifth control described above is not ensured, the non-reverse flow allowable time may include the third time.

  No. shown in FIG. In the control 5, the allowable backward flow time includes at least a first time (non-power generation time). Here, when the execution of the above-described fourth control is ensured, the allowable reverse power flow time may include the second time. Similarly. When the execution of the sixth control described above is secured, the allowable backward flow time may include the third time. In such a case, the non-reverse power flow allowable time is a time (power generation time) excluding at least the first time. When the execution of the fourth control described above is not ensured, the non-reverse power flow allowable time may include the second time. Similarly, when the execution of the sixth control described above is not ensured, the non-reverse power flow allowable time may include the third time.

  In the first modification, No. 1 shown in FIG. 1 and no. In the control of 2, since the reverse power flow from the storage battery device 320 is not permitted, there is no concept of at least the reverse power flow allowable time. However, even in such a case, it may be specified or set that the allowable backward flow time is zero, or may be specified or set that the allowable non-reverse flow time is all.

  Similarly, No. 1 shown in FIG. In the control of No. 4, since the reverse power flow from the storage battery device 320 is not limited, at least the concept of non-reverse power flow allowable time does not exist. However, even in such a case, it may be specified or set that the non-reverse power flow allowable time is zero, or may be specified or set that the reverse power flow allowable time is all.

  In the first modification, the security of execution of the third control to the sixth control may be performed by an operator such as a power generation company, a power transmission / distribution company, or a retailer, and is entrusted by these companies. It may be done by a tripartite organization.

[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, the solar cell device 310 is illustrated as a distributed power source provided together with the storage battery device 320. However, the embodiment is not limited to this. The distributed power source may be a distributed power source that uses natural energy such as wind power or geothermal heat.

  Although not specifically mentioned in the embodiment, the local control device 360 provided in the facility 300 may not necessarily be provided in the facility 300. For example, some of the functions of the local control device 360 may be provided by a cloud server provided on the Internet. That is, it may be considered that the local control device 360 includes a cloud server.

  In the embodiment, the case where the control device that controls the storage battery device 320 is the local control device 360 (EMS) is exemplified. However, such a control device may be a PCS constituting the storage battery device 320. Further, such a control device may be a server (for example, the power management server 200) provided outside the facility 300.

  In the embodiment, the case where the local control device 360 is an EMS is illustrated. However, the embodiment is not limited to this. The local control device 360 may be a PCS provided in the storage battery device 320 or a remote controller that controls the PCS provided in the storage battery device 320.

  In the embodiment, the case where the first protocol is a protocol conforming to Open ADR2.0 and the second protocol is a protocol conforming to ECHONET Lite is illustrated. However, the embodiment is not limited to this. The first protocol may be a protocol standardized as a protocol used for communication between the power management server 200 and the local control device 360. The second protocol may be a protocol standardized as a protocol used in the facility 300.

  DESCRIPTION OF SYMBOLS 100 ... Power supply control system, 110 ... Electric power system, 120 ... Network, 200 ... Power management server, 210 ... Management part, 220 ... Communication part, 230 ... Control part, 300 ... Facility, 310 ... Solar cell apparatus, 320 ... Storage battery apparatus , 330 ... Load, 340 ... Wattmeter, 350 ... Wattmeter, 360 ... Local controller, 361 ... First communication unit, 362 ... Second communication unit, 363 ... Control unit, 400 ... Electric power company

Claims (11)

Step A for controlling the storage battery device;
A step B for controlling a distributed power source that is allowed to reverse power flow to the power system,
The step A includes a condition indicating whether or not reverse power flow from the storage battery device to the power system is permitted, and whether or not the storage battery device is allowed to assist reverse power flow from the distributed power source to the power system. The power supply control method including the step which controls the said storage battery apparatus based on the conditions which show.   In the step A, when a reverse power flow from the storage battery device to the power system is allowed, the storage battery device can be used in a non-power generation time other than the power generation time of the distributed power source regardless of the power consumption of the load device. The power supply control method according to claim 1, further comprising a step of performing a control that allows a discharge operation to be performed.   In the step A, when a reverse power flow from the storage battery device to the power system is not permitted, the storage battery does not exceed the power consumption of the load device in a non-power generation time other than the power generation time of the distributed power source. The power supply control method according to claim 1, further comprising a step of performing control that allows the apparatus to perform a discharging operation.   The step A is performed when the reverse power flow from the storage battery device to the power system is allowed and when the storage battery device is allowed to assist the reverse power flow from the distributed power source to the power system, The power supply according to any one of claims 1 to 3, further comprising a step of performing control to allow the storage battery device to perform a discharge operation regardless of power consumption of a load device during a power generation time of a distributed power supply. Control method.   In the step A, when the storage battery device is allowed to assist reverse power flow from the distributed power source to the power system, and the generated power amount of the distributed power source is greater than or equal to the power consumption amount of the load device, the distributed power source 5. The method according to claim 1, further comprising a step of performing control to allow the storage battery device to perform a discharge operation within a range that does not exceed a power consumption amount of the load device during a power generation time of a power source. Power control method.   In the step A, when the storage battery device is not allowed to assist reverse power flow from the distributed power source to the power system, and the generated power amount of the distributed power source is greater than or equal to the power consumption amount of the load device, The power supply control method according to any one of claims 1 to 5, including a step of performing control for suppressing a discharge operation of the storage battery device during a power generation time of a distributed power supply.   In the step A, when the storage battery device is allowed to assist reverse power flow from the distributed power source to the power system and the generated power amount of the distributed power source is smaller than the power consumption amount of the load device, the distributed power source The power supply control method according to any one of claims 1 to 6, further comprising a step of performing control to allow discharge operation of the storage battery device within a range that does not exceed power consumption of the load device during power generation time of the power supply. .   In the step A, when the storage battery device is not allowed to assist reverse power flow from the distributed power source to the power system, and the generated power amount of the distributed power source is smaller than the power consumption amount of the load device, the step A The power generation time of the distributed power source includes a step of performing control to allow the discharging operation of the storage battery device in a range not exceeding the power amount obtained by removing the power generation amount of the distributed power source from the power consumption amount of the load device. The power supply control method according to any one of claims 1 to 7.   At least one of a reverse power flow allowable time in which reverse power flow from the storage battery device is allowed and a non-reverse power flow allowable time in which the reverse power flow of the storage battery device is not allowed is provided in a facility having the storage battery device and the distributed power source The power supply control method according to any one of claims 1 to 8, which is specified by a power management server that manages a local control device.   At least one of a reverse flow allowable time in which reverse flow from the storage battery device is allowed and a non-reverse flow allowable time in which reverse flow of the storage battery device is not allowed is provided in a facility having the storage battery device and the distributed power source The power supply control method according to claim 1, wherein the power supply control method is set in a local control device. A control unit for controlling a distributed power source that allows reverse power flow to the storage battery device and the power system,
The control unit determines whether or not reverse power flow from the storage battery device to the power system is allowed and whether or not the storage battery device is allowed to assist reverse power flow from the distributed power source to the power system. The control apparatus which controls the said storage battery apparatus based on the conditions which show.

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