JP6516156B2 - Relay management device, storage system - Google Patents

Description

  The present invention relates generally to a relay management device and a storage system, and more particularly to a relay management device and a storage system for relaying communication between a control device and a storage device.

  BACKGROUND Conventionally, there is a power supply system that includes a power storage device at a customer facility and supplies power from the power storage device to a load. The storage device is charged using commercial power or the like. For example, in Patent Document 1, the charge control unit controls charging of the storage device. Specifically, the charge control unit performs charge control so as to increase the charge amount of the storage battery than that in the steady state, when acquiring information on a disaster occurrence forecast.

JP, 2009-148070, A

  Conventionally, when there are a plurality of power storage devices, the charge control unit individually controls each of the power storage devices. In this case, the load required to control the plurality of power storage devices becomes large, and the control of the plurality of power storage devices can not be performed simply. On the other hand, there is still a demand for individual control.

  That is, when there are a plurality of power storage devices, it is possible to flexibly select the control mode of the power storage device, and to provide a relay management device and a power storage system capable of improving the convenience of control of the power storage device.

  The relay management device according to the present invention is a relay management device that relays communication between one or more power storage devices and a control device that controls charging and discharging of the power storage devices, using the first communication protocol. A first communication unit communicating with the control device, a second communication unit communicating with the power storage device using a second communication protocol, and a signal based on a signal received by the first communication unit from the second communication unit A relay control unit that causes a transmission based on a signal received by the second communication unit to be transmitted from the first communication unit, and a group setting that sets group identification information for a group consisting of two or more power storage devices; Or an identification information setting unit configured to set individual identification information for each power storage device, and the first communication unit is configured to set the group identification information and the individual identification information by the identification information setting unit. Result is transmitted to the control device, and the relay control unit receives the first control signal to which the group identification information or the individual identification information is added from the second communication unit when the first communication unit receives the first control signal. A second control signal based on the first control signal is transmitted to a power storage device corresponding to group identification information or the individual identification information.

  The storage system of the present invention includes one or more storage devices, a control device for controlling charging and discharging of the storage device, and a relay management device for relaying communication between the storage device and the control device. The relay management device includes a first communication unit that communicates with the control device using a first communication protocol, a second communication unit that communicates with the power storage device using a second communication protocol, and the first communication. A relay control unit that causes a signal based on the signal received by the unit to be transmitted from the second communication unit, and a signal based on the signal received by the second communication unit to be transmitted from the first communication unit, and two or more power storage devices And an identification information setting unit for setting individual identification information for individual power storage devices, and group identification information setting for the group consisting of Information setting Transmitting the setting result of the group identification information and the individual identification information to the control device, the control device holds the setting result of the group identification information and the individual identification information, and transmits the group identification information or the individual By transmitting a signal to which identification information is added, communication is performed with the power storage device via the relay management device.

  As described above, according to the present invention, when there are a plurality of power storage devices, the control mode of the power storage device can be flexibly selected, and the convenience of control of the power storage device can be improved.

FIG. 1 is a block diagram showing a configuration of a power storage system in which a relay management device of Embodiment 1 is used. It is a block diagram which shows the structure of the electrical storage system in which the relay management apparatus of Embodiment 2 is used. It is a block diagram which shows the structure of the electrical storage system in which the relay management apparatus of Embodiment 3 is used.

  Hereinafter, embodiments of the present invention will be described based on the drawings.

(Embodiment 1)
FIG. 1 shows the entire configuration of a storage system A1. The storage system A 1 mainly includes a control device 1, a relay management device 2, and a plurality of storage devices 3, and supplies power to the load 5 via the distribution board 4. When the plurality of power storage devices 3 are distinguished from each other, the power storage devices 31, 32, and 33 may be separated. . . Use the sign of In FIG. 1, solid lines between components indicate power paths, and alternate long and short dashed lines between components indicate communication paths. Moreover, although the form which applied electrical storage system A1 to the dwelling unit of a detached house is demonstrated in this embodiment, you may apply electrical storage system A1 to customer's facilities, such as a collective housing and a business establishment.

  Distribution board 4 is supplied with AC power (commercial power) from commercial power supply 8 via power system L1, and AC power (discharged power) from power storage device 3. And the electricity distribution panel 4 equips the panel with a master breaker, several branch breakers, a switch, etc. The distribution board 4 supplies AC power to the load 5 via the branch circuits L2 of a plurality of systems branched at each load side of the plurality of branch breakers. The load 5 is an electrical device such as a lighting device, an air conditioner, or an information device connected to the branch circuit.

  Power storage device 3 includes a power conditioner 3a and a storage battery 3b.

  Power conditioner 3a has a function of charging and discharging storage battery 3b. Specifically, the power conditioner 3a converts AC power supplied from the distribution board 4 into DC power to charge the storage battery 3b. Further, the power conditioner 3a converts direct current power supplied from the storage battery 3b into alternating current power (discharge power) and supplies it to the distribution board 4 to discharge the storage battery 3b. The discharge power is supplied to the electric power system L1 through the distribution board 4 and is supplied to the load 5 from the distribution board 4 through the branch circuit L2. Furthermore, the power conditioner 3a has a function of adjusting the frequency of the discharge power to be output and the output voltage so as to enable grid interconnection with the power system L1.

  The power conditioner 3 a is configured to be able to communicate with the control device 1 via the relay management device 2. The control device 1 can monitor and control the power storage device 3 by communicating with the power conditioner 3 a via the relay management device 2. Hereinafter, monitoring and control of the power storage device 3 performed by the control device 1 via the relay management device 2 will be described in detail.

  First, as a communication protocol used for communication between the control device 1 and the relay management device 2, for example, the ECHONET Lite (registered trademark) standard or the like is used. The communication protocol used in the communication between the control device 1 and the relay management device 2 will be hereinafter referred to as the first communication protocol, but the specific communication protocol is not limited.

  Further, as a communication protocol used for communication between the relay management device 2 and the power conditioner 3a, for example, the Modbus (registered trademark) standard or the like is used. The communication protocol used in the communication between the relay management device 2 and the power conditioner 3a is hereinafter referred to as the second communication protocol, but the specific communication protocol is not limited. However, in the present embodiment, the first communication protocol and the second communication protocol are different communication protocols. The first communication protocol and the second communication protocol may be the same communication protocol.

  The communication method between the control device 1 and the relay management device 2 is selected from wireless communication using radio waves as a transmission medium, wired communication using a dedicated line or a power line as a transmission medium, and the like. The communication method between the relay management device 2 and the power conditioner 3a is also selected from wireless communication using radio waves as a transmission medium, wired communication using a dedicated line or a power line as a transmission medium, and the like.

  Then, relay management device 2 relays communication between control device 1 and power conditioner 3a (power storage device 3). The relay management device 2 includes a first communication unit 2a, a second communication unit 2b, a relay control unit 2c, an identification information setting unit 2d, an operation unit 2e, a display unit 2f, a storage unit 2g, and a test unit. And 2h.

  The first communication unit 2a has a function of communicating with the control device 1 using a first communication protocol.

  The second communication unit 2 b has a function of communicating with the power conditioner 3 a (the power storage device 3) using the second communication protocol.

  When the first communication unit 2a receives a signal, the relay control unit 2c transmits a signal based on the received signal from the second communication unit 2b, and when the second communication unit 2b receives a signal, the relay control unit 2c receives the signal. A signal based on the received signal is transmitted from the first communication unit 2a. That is, relay control unit 2c controls relay processing between control device 1 using the first communication protocol and power storage device 3 using the second communication protocol. As a result, based on the signal transmitted by the control device 1 using the first communication protocol, the relay management device 2 transmits a signal of the second communication protocol to the power storage device 3. Further, based on the signal transmitted by the power storage device 3 using the second communication protocol, the relay management device 2 transmits a signal of the first communication protocol to the control device 1.

  Identification information setting unit 2d sets individual identification information for each power storage device 3 individually, or sets group identification information for one or more groups of two or more power storage devices 3. I do.

  The individual setting and the group setting are performed by the user operation of the operation unit 2e. Operation unit 2e includes, for example, a push button switch, a slide switch, and the like. Furthermore, the display unit 2 f includes a display unit of a 7-segment display (Seven Segment Display) that displays setting progress, setting results, and the like by the operation unit 2 e. When the display unit 2 f is, for example, a touch panel type display, the display unit 2 f may double as the operation unit 2 e.

  First, the identification information setting unit 2 d causes the second communication unit 2 b to broadcast an acquisition request for device information, and acquires device information returned from each of the power storage devices 3. The device information is, for example, a MAC address uniquely assigned to each of the power storage devices 3 in advance. The identification information setting unit 2d assigns identification information to each piece of device information of the power storage device 3 in accordance with a user operation of the operation unit 2e. The identification information setting unit 2 d associates the device information of the power storage device 3 with the identification information, and stores the identification information in the storage unit 2 g which is a non-volatile memory. That is, the correspondence between the device information and the identification information is stored in the storage unit 2 g for each power storage device 3. In the present embodiment, the power storage devices 31, 32, and 33. . . The device information of each of “M1”, “M2”, “M3”. . . I assume.

  For example, when individually setting each of power storage devices 31, 32, and 33, identification information setting unit 2d assigns individual identification information "X1" to the device information "M1" of power storage device 31, and sets the device information of power storage device 32 ". The individual identification information “X2” is allocated to “M2”, and the individual identification information “X3” is allocated to the device information “M3” of the storage device 33. In this case, the storage unit 2g stores the correspondence between the device information and the identification information shown in Table 1.

  Then, the identification information setting unit 2d transmits the data of the allocated individual identification information “X1”, “X2”, and “X3” to the control device 1 as the setting result of the identification information. The control device 1 stores (holds) the setting result of the identification information in the memory to know the individual identification information “X1”, “X2”, “X3” set in each storage device 3 to be controlled. Can. That is, control device 1 recognizes that individual power storage devices 3 for which individual identification information is set are one control target.

  When identification information setting unit 2d individually sets each of power storage devices 31, 32, and 33, control device 1 uses power storage device 31 using individual identification information "X1", "X2", and "X3", respectively. Each of 32, 33 can be controlled individually.

  For example, the control device 1 controls the control signal to which the individual identification information "X1" is added, the control signal to which the individual identification information "X2" is added, and the control signal to which the individual identification information "X3" is added. Send using a communication protocol. The control signal is a signal that instructs the power storage device 3 on the control content. The control contents include, for example, "charge", "discharge", "monitor" and the like. The control content "charging" instructs charging of the storage battery 3b. The control content "discharge" instructs discharge of the storage battery 3b. The control content "monitoring" instructs to reply storage battery information such as the rated capacity, remaining capacity, charging current, and discharging current of the storage battery 3b. The control signal transmitted by the control device 1 using the first communication protocol is hereinafter referred to as a first control signal.

  In the relay management device 2, the first communication unit 2 a receives the first control signal transmitted from the control device 1. Relay control unit 2c refers to storage unit 2g to recognize device information corresponding to the individual identification information added to the first control signal, and sets power storage device 3 corresponding to the recognized device information as a control target A control signal is transmitted from the second communication unit 2b. The control signal transmitted by the second communication unit 2b includes control content instructing the power storage device 3, and the control content is the same as the control content included in the received first control signal. .

  In this case, the second communication unit 2b performs second control on the control signal to which the device information "M1" is added, the control signal on which the device information "M2" is added, and the control signal on which the device information "M3" is added. Send using a communication protocol. The control signal transmitted by the relay management device 2 (second communication unit 2b) using the second communication protocol is hereinafter referred to as a second control signal.

  Power conditioner 3a of power storage device 3 receives the second control signal when the device information added to the second control signal matches the device information of the own device. The power conditioner 3a executes the control content instructed by the received second control signal. In this case, the power conditioner 3a of the power storage device 31 receives the second control signal to which the device information "M1" is added. Further, power conditioner 3a of power storage device 32 receives the second control signal to which the device information "M2" is added. Further, the power conditioner 3a of the power storage device 33 receives the second control signal to which the device information "M3" is added. Power conditioners 3a of power storage devices 31, 32, 33 execute control contents of "charge", "discharge" or "monitor" based on the received second control signal.

  When the control content is "charge", power conditioner 3a performs charge control of storage battery 3b. Further, when the control content is "discharge", power conditioner 3a performs discharge control of storage battery 3b.

  In addition, when the control content is “monitoring”, the power conditioner 3a transmits a monitoring signal including storage battery information using the second communication protocol.

  In the relay management device 2, the second communication unit 2b receives the monitoring signal transmitted from the power conditioner 3a. If the transmission source of the monitoring signal is power storage device 31, relay control unit 2c can recognize that the monitoring signal corresponds to individual identification information "X1". Therefore, relay control unit 2c causes first communication unit 2a to transmit a monitoring signal including storage battery information of power storage device 31. In this case, the first communication unit 2a transmits a monitoring signal including the storage battery information of the storage device 31 and the individual identification information "X1" of the storage device 31 using the first communication protocol.

  The monitoring signal transmitted by the relay management device 2 (first communication unit 2a) using the first communication protocol is hereinafter referred to as a first monitoring signal. Further, the monitoring signal transmitted by the power conditioner 3a using the second communication protocol is hereinafter referred to as a second monitoring signal.

  The control device 1 can receive the first monitoring signal, and use the storage battery information included in the first monitoring signal to instruct subsequent charge control and discharge control of the power storage device 31. The relay management device 2 relays the second monitoring signal transmitted by the power storage devices 32 and 33 to which the individual identification information “X2” and “X3” are allocated in the same manner as described above.

  In addition, when the power storage devices 31, 32, and 33 are set as a group, the identification information setting unit 2d allocates group identification information "G1" to a group including the power storage devices 31, 32, and 33. In this case, the storage unit 2g stores the correspondence between the device information and the identification information shown in Table 2.

  Then, the identification information setting unit 2d transmits data of the allocated group identification information “G1” to the control device 1 as a result of setting the identification information. The control device 1 can store (hold) the setting result of the identification information in the memory, and can know the group identification information “G1” set to the group to be controlled. That is, the control device 1 recognizes that each group in which the group identification information is set is one control target. Therefore, control device 1 collectively controls power storage devices 31, 32, 33 in the group by transmitting one first control signal for controlling the group to which group identification information "G1" is set. can do.

  For example, the control device 1 transmits a first control signal to which group identification information "G1" is added.

  In the relay management device 2, the first communication unit 2 a receives the first control signal transmitted from the control device 1. The relay control unit 2c refers to the storage unit 2g to recognize and recognize the device information "M1," "M2" and "M3" corresponding to the group identification information "G1" added to the first control signal. A second control signal to which each of the device information is added is transmitted from the second communication unit 2b. In this case, the second communication unit 2b generates a second control signal to which the device information "M1" is added, a second control signal to which the device information "M2" is added, and a second control to which the device information "M3" is added. Send each signal. Power conditioners 3a of power storage devices 31, 32, 33 execute control contents of "charge", "discharge" or "monitor" based on the received second control signal.

  When the control content is "charge", power conditioner 3a performs charge control of storage battery 3b. Further, when the control content is "discharge", power conditioner 3a performs discharge control of storage battery 3b.

  Moreover, the power conditioner 3a transmits the 2nd monitoring signal containing storage battery information, when control content is "monitoring."

  In the relay management device 2, the second communication unit 2b receives the second monitoring signal transmitted from the power conditioners 3a of the power storage devices 31, 32, and 33. Since the transmission source of the second monitoring signal is any one of the power storage devices 31, 32, and 33, the relay control unit 2c can recognize it as the second monitoring signal transmitted from the group of the group identification information "G1." Therefore, relay control unit 2c combines storage battery information (rated capacity, remaining capacity, charge current, discharge current, etc.) of power storage devices 31, 32, 33 into one storage battery information, and includes the storage battery information. A monitoring signal is transmitted from the first communication unit 2a. Here, of the storage battery information, the rated capacity and the remaining capacity correspond to the capacity information.

  Specifically, relay control unit 2c sets the total value of the rated capacities of each of power storage devices 31, 32, 33, the total value of remaining capacity, the total value of charging current, and the total value of discharging current as one storage battery information. . Then, the relay control unit 2c causes the first communication unit 2a to transmit the first monitoring signal to which the storage battery information summarized into one and the group identification information "G1" are added. That is, relay management device 2 transmits storage battery information in group units to control device 1.

  The control device 1 can receive the first monitoring signal and can use the storage battery information included in the first monitoring signal to instruct charge control and discharge control in group units.

  Further, it is assumed that the number of power storage devices 3 in the same group is increased (changed) by the setting process by the identification information setting unit 2d. In this case, the second communication unit 2b acquires storage battery information from each of the power storage devices 3 that form a group in which the power storage device 3 has increased or decreased. Then, relay control unit 2c combines the storage battery information of the plurality of power storage devices 3 into one storage battery information as described above, and adds the storage battery information and the group identification information to the first monitoring signal from first communication unit 2a. Send it.

  Therefore, since the control device 1 can update storage battery information of a group in which the power storage device 3 has increased or decreased, the control device 1 can appropriately instruct charge control and discharge control in group units.

  In addition, the identification information setting unit 2d can individually set some of the power storage devices 3 for the plurality of power storage devices 3 and set other power storage devices 3 as a group. Further, the identification information setting unit 2d can create a plurality of groups by group setting.

  Further, the control device 1 is connected to a wide area network 100 including the Internet and the like via a smart meter or a router, a home gateway and the like for remote meter reading of electric power installed at a customer facility. The control device 1 can communicate with the upper server 200 on the wide area network 100. The upper server 200 is managed by a power company or an aggregator. The power company or the aggregator causes the upper server 200 to transmit various requests to the control device 1 of the customer facility based on the balance of supply and demand of the commercial power of the power system L1. Control device 1 can determine the control content of power storage device 3 based on a request from higher-level server 200 and can transmit a control signal to power storage device 3.

  The control content instructed by the first control signal transmitted from the control device 1 may be an operation mode other than the “charge”, “discharge”, and “monitor” described above. The operation mode includes a storage priority mode, an economic priority mode, and the like. The storage priority mode is an operation mode in which the storage battery 3b is always maintained in a fully charged state. The economic priority mode is an operation mode in which the storage battery 3b is charged using late-night power with a low charge unit price, and the consumption of commercial power is suppressed using discharge power of the storage battery 3b in the daytime. Relay management device 2 converts a first control signal instructing the operation mode into a second control signal instructing the operation mode, and transmits the second control signal to power storage device 3 to be controlled. Power conditioner 3a of power storage device 3 performs charge control and discharge control of storage battery 3b in the instructed operation mode.

  As described above, relay management device 2 relays communication between one or more power storage devices 3 and control device 1 that controls charging and discharging of power storage devices 3. The relay management device 2 includes a first communication unit 2a, a second communication unit 2b, a relay control unit 2c, and an identification information setting unit 2d. The first communication unit 2a communicates with the control device 1 using a first communication protocol. The second communication unit 2b communicates with the power storage device 3 using the second communication protocol. The relay control unit 2c causes the second communication unit 2b to transmit a signal based on the signal received by the first communication unit 2a, and causes the first communication unit 2a to transmit a signal based on the signal received by the second communication unit 2b. The identification information setting unit 2 d performs group setting for setting group identification information to a group consisting of two or more power storage devices 3 or individual setting for setting individual identification information for each power storage device 3. Then, the first communication unit 2a transmits, to the control device 1, the setting result of the group identification information and the individual identification information by the identification information setting unit 2d. Furthermore, it is assumed that the first communication unit 2a receives a first control signal to which group identification information or individual identification information is added. In this case, relay control unit 2c causes second communication unit 2b to transmit a second control signal based on the first control signal to power storage device 3 corresponding to the group identification information or the individual identification information.

  That is, in the relay management device 2, not only the individual setting in which the identification information setting unit 2 d sets the individual identification information for each power storage device 3 but also the group identification for the group consisting of two or more power storage devices 3 You can configure group settings to set information. Then, the relay management device 2 transmits the setting result of the group identification information and the individual identification information by the identification information setting unit 2 d to the control device 1. Therefore, control device 1 can recognize each group in which group identification information is set as one control target, and can recognize each power storage device 3 in which individual identification information is set as one control target. . As a result, when controlling the plurality of power storage devices 3 in the same group, the control device 1 transmits one first control signal to which the group identification information is added, to thereby control the plurality of power storage devices 3 in the group. Can be controlled. Further, the control device 1 can individually control the power storage device 3 by transmitting the first control signal to which the individual identification information is added for each power storage device 3. Therefore, by using relay management device 2, when there are a plurality of power storage devices 3, the control form of power storage device 3 can be flexibly selected, and the convenience of control of power storage device 3 can be improved.

  The relay management device 2 preferably includes a power conditioner 3 a that charges and discharges the storage battery 3 b and the storage battery 3 b.

  Further, the storage system A1 described above includes one or more storage devices 3, a control device 1, and a relay management device 2. Control device 1 controls charging and discharging of power storage device 3. Relay management device 2 relays communication between power storage device 3 and control device 1.

  The relay management device 2 includes a first communication unit 2a, a second communication unit 2b, a relay control unit 2c, and an identification information setting unit 2d. The first communication unit 2a communicates with the control device 1 using a first communication protocol. The second communication unit 2b communicates with the power storage device 3 using the second communication protocol. The relay control unit 2c causes the second communication unit 2b to transmit a signal based on the signal received by the first communication unit 2a, and causes the first communication unit 2a to transmit a signal based on the signal received by the second communication unit 2b. The identification information setting unit 2 d performs group setting for setting group identification information to a group consisting of two or more power storage devices 3 or individual setting for setting individual identification information for each power storage device 3. Then, the first communication unit 2a transmits, to the control device 1, the setting result of the group identification information and the individual identification information by the identification information setting unit 2d. The control device 1 holds the setting result of the group identification information and the individual identification information, and transmits a signal to which the group identification information or the individual identification information is added. Communicate with

  Therefore, in the storage system A1, when there are a plurality of storage devices 3, the control form of the storage device 3 can be flexibly selected, and the convenience of control of the storage device 3 can be improved.

  Further, it is assumed that the number of power storage devices 3 constituting the group is changed. In this case, it is preferable that the second communication unit 2b acquire capacity information, which is information related to the capacity of electric storage, from each of the electric storage devices 3 forming the group. Then, relay control unit 2c causes first communication unit 2a to transmit the sum of the capacities of power storage devices 3 constituting the group from control unit 1 as capacity information of the group.

  In this case, the control device 1 can easily update the capacity information of the group in which the number of power storage devices 3 has increased or decreased. Therefore, even when the number of power storage devices 3 in a group increases or decreases, control device 1 can appropriately issue charge control and discharge control instructions on a group basis.

  Next, a test operation by the test unit 2h will be described.

  First, the test unit 2 h causes the second communication unit 2 b to transmit a second control signal for test (hereinafter referred to as a test signal) by user operation of the operation unit 2 e. A storage device 3 or a group of two or more storage devices 3 is selected as a test target by the operation of the operation unit 2e, and the test unit 2h generates a test signal for instructing a specific control content to the test target. In response to the operation of the operation unit 2e, transmission is performed from the second communication unit 2b. Power conditioner 3a of power storage device 3 having received the test signal executes the instructed control content based on the test signal, and transmits the execution result to relay management device 2. In the relay management device 2, the display unit 2f displays the execution result, so that the user can know whether or not the storage device 3 has successfully executed the instruction by the test signal. In addition, control contents instructed by the test signal can be set as “charge”, “discharge”, “monitor”, “storage priority mode”, “economic priority mode” and the like.

  That is, it is preferable that the second communication unit 2 b further include a display unit 2 f that displays information related to the power storage device 3 acquired from the power storage device 3.

  In this case, even when the control device 1 is not present, the relay management device 2 can display the information related to the power storage device 3, which improves the convenience.

  The relay management device 2 preferably further includes a test unit 2 h that transmits a control signal for test from the second communication unit 2 b to perform a test operation of the power storage device 3. In this case, the display unit 2f preferably displays the result of the test operation.

  Therefore, even when the control device 1 is not installed at the time of construction of the storage system A1, the relay management device 2 can check the operation of the storage device 3.

Second Embodiment
FIG. 2 shows the entire configuration of the storage system A2. The relay management device 2A differs from the relay management device 2 of the first embodiment in that the relay management device 2A further includes a control setting unit 2i. The same components as those of the first embodiment are denoted by the same reference numerals and the description thereof is omitted.

  Here, a service using a demand response for power peak cut is proposed by a power company or an aggregator. This demand response uses a demand response (Demand Response) signal to the customer to reduce the amount of commercial power used during the target period if the amount of power demand is predicted to be tight with respect to commercial power. Request in advance. The demand response signal is a signal transmitted from the upper server 200 to the control device 1 and corresponds to a power reduction request. Hereinafter, the demand response signal is referred to as a DR signal.

  The DR signal includes information on the power reduction request target period and the amount of reduced power. The target period is a period for requesting a reduction in the use amount of commercial power (that is, a reduction in the commercial power supplied from the commercial power source 8 to the customer's facility). The reduced power amount is the reduced power amount of the commercial power required in the target period.

  Then, when the control device 1 receives the DR signal, the control device 1 is a group consisting of individual identification information (individual power storage devices 3) and group identification information (a plurality of power storage devices 3) based on the reduced power amount requested by the DR signal. The amount of discharge power is associated with each of That is, the sum of the amounts of discharged power associated with the individual identification information and the group identification information is equal to the amount of reduced power requested by the DR signal. The control device 1 includes a first control signal to which individual identification information or group identification information, information on the amount of discharge energy associated with the identification information (individual identification information or group identification information), and information on a target period are added. Send.

  For example, when individual identification information "X1", "X2", and "X3" are allocated to each of power storage devices 31, 32, and 33, control device 1 which has received the DR signal has individual identification information "X1", The first control signal in which “X2” and “X3” are respectively set is transmitted.

  Then, relay management device 2A transmits a second control signal to each of power storage devices 31, 32, and 33 based on the first control signal. The second control signal includes device information of the power storage device 3 to be controlled, information on the amount of discharged power instructed to the control target, and information on the target period. In each of power storage devices 31, 32, 33, power conditioner 3a performs discharge control for discharging the instructed amount of discharged power from storage battery 3b in the target period instructed by the second control signal. Therefore, the amount of reduced power requested by the DR signal can be covered by the discharge power of each of power storage devices 31, 32, 33.

  Further, when group identification information "G1" is assigned to the group formed of power storage devices 31, 32, and 33, control device 1 which receives the DR signal has group identification information "G1" as a control target. The set first control signal is transmitted to the relay management device 2A. The control setting unit 2i of the relay management device 2A has a function of setting the control content for each of the power storage devices 31, 32, and 33 constituting the group based on the first control signal.

  For example, it is assumed that a discharge power amount of 12 KWh (first discharged power amount) is allocated to the group consisting of power storage devices 31, 32, and 33 by the first control signal. Control setting unit 2i instructs each of power storage devices 31, 32, 33 to have a discharge power amount (second discharge power amount) such that the sum of the respective discharge power amounts of power storage devices 31, 32, 33 matches 12 KWh. Set). That is, control setting unit 2i divides 12 KWh and distributes it to each of power storage devices 31, 32, and 33. As a specific allocation method by the control setting unit 2i, there are the following first allocation method and second allocation method.

  The first distribution method is the amount of discharged power (the second amount of discharged power) for instructing each of the plurality of power storage devices 3 constituting the group to have a value obtained by dividing 12 KWh by the number of power storage devices 3 constituting the group It is a way to In this method, when the first control signal allocates a discharge power of 12 KWh to a group consisting of power storage devices 31, 32, and 33, control setting unit 2i instructs power storage devices 31, 32, and 33, respectively. Set the discharge power amount to 4 kWh. That is, the amount of discharged power is set equally to each of power storage devices 31, 32, and 33.

  The second distribution method is an amount of discharged power that is instructed to each of the plurality of power storage devices 31, 32, and 33 that configure the group based on the respective priorities of the plurality of power storage devices 3 that configure the group (second discharge Power amount).

  First, the second communication unit 2b of the relay management device 2A has a remaining capacity acquiring function, and periodically acquires information on the remaining capacity of the storage battery 3b from the power conditioners 3a of the power storage devices 31, 32, and 33, respectively. And store it in the storage unit 2g. Then, control setting unit 2i sets, for each of power storage devices 31, 32, and 33, a higher priority as the remaining capacity increases. Here, storage devices 31 → storage devices 32 → storage devices 33 are listed in descending order of remaining capacity: priority of storage device 31 is “1”, priority of storage device 32 is “2”, priority of storage device 33 The ranking is "3". In this method, when the first control signal allocates a discharge power of 12 KWh to a group consisting of power storage devices 31, 32 and 33, control setting unit 2i instructs discharge power to increase as the priority is higher Increase the second discharge power amount). Specifically, control setting unit 2i sets the amount of discharged power instructed to power storage device 31 to 6 KWh, sets the amount of discharged power instructed to power storage device 32 to 4 KWh, and sets the discharged power amount instructed to power storage device 32. Set to 2 kWh. Note that control setting unit 2i determines the upper limit value of the amount of discharged power instructed to each of power storage devices 31, 32, 33 based on the amount of power that each of power storage devices 31, 32, 33 can discharge. Is preferred.

  In addition, the priority order may be determined according to each application (attribute) of power storage devices 31, 32, and 33. For example, it is assumed that the application of power storage devices 31 and 32 is peak suppression of power demand, and the application of power storage device 33 is backup at the time of a power failure. In this case, since it is preferable to maintain the fully charged state as much as possible of the power storage device 33 used for backup application at the time of a power failure, the priority is set lower than the power storage devices 31 and 32. Specifically, control setting unit 2i sets the discharged power amount instructed to power storage devices 31 and 32 to 5 KWh, and sets the discharged power amount instructed to power storage device 33 to 2 KWh.

  Then, relay management device 2A transmits the second control signal to each of power storage devices 31, 32, and 33. The second control signal includes device information of the power storage device 3 to be controlled, information on the amount of discharged power instructed to the control target, and information on the target period. In each of power storage devices 31, 32, 33, power conditioner 3a performs discharge control for discharging the instructed amount of discharged power from storage battery 3b in the target period instructed by the second control signal. Therefore, the amount of reduced power requested by the DR signal can be covered by the discharge power of each of power storage devices 31, 32, 33.

  The method of determining the priority by the control setting unit 2i may be another method.

  It is preferable that the above-described relay management device 2A further includes a control setting unit 2i that sets control content to be instructed to each of the plurality of power storage devices 3 forming a group.

  In this case, the relay management device 2A can individually set, for each power storage device 3, the control content to be instructed to each of the plurality of power storage devices 3 in the same group.

  In addition, when the first communication unit 2a receives the first control signal to which the group identification information is added, the control setting unit 2i causes each of the plurality of power storage devices 3 forming the group to be based on the first control signal. It is preferable to set the control content to be instructed. Then, relay control unit 2c causes second communication unit 2b to transmit a second control signal instructing the control content to each of the plurality of power storage devices 3 constituting the group.

  In this case, the relay management device 2A can individually set the control content corresponding to each of the plurality of power storage devices 3 based on the first control signal for controlling the group unit.

  Also, it is assumed that the discharge of the first discharge power amount is instructed to the group by the first control signal. In this case, the control setting unit 2i divides the first discharge power amount and distributes the second discharge power amount distributed to each of the plurality of power storage devices 3 configuring the group into a plurality of power storage devices 3 configuring the group. It is preferable to set as control content instructed to each of the above.

  Therefore, relay management device 2A can individually set the amount of discharged power instructed to each of the plurality of power storage devices 3 based on the first control signal for which discharge control is performed in group units.

  Further, the control setting unit 2i divides the first discharge power amount by the number of the plurality of power storage devices 3 forming the group into a second discharge power amount corresponding to each of the plurality of power storage devices 3 forming the group. It is preferable to

  In this case, relay management device 2A can evenly distribute the amount of discharged power to the plurality of power storage devices 3 forming the group.

  In addition, the control setting unit 2i may set the second discharge power amount corresponding to each of the plurality of power storage devices 3 constituting the group based on the respective priorities of the plurality of power storage devices 3 constituting the group. preferable.

  In this case, relay management device 2A can individually set the amount of discharged power in accordance with the respective priorities of power storage devices 3. Therefore, relay management device 2A can individually set the amount of discharged power in accordance with each state and attribute of power storage device 3.

  Further, the control setting unit 2i performs charge control of the storage battery 3b of the power storage device 3 to be controlled individually or in groups before the target period of the power reduction request, and the storage battery 3b in a fully charged state in the target period. Is preferably discharged.

(Embodiment 3)
FIG. 3 shows the configuration of the main part of the storage system A3. In power storage system A3, in power storage devices 31, 32, and 33, AC power obtained by power conditioner 3a converting the discharge power of storage battery 3b is supplied only to dedicated loads 61, 62, and 63, respectively. In power storage devices 31, 32, and 33, power conditioner 3a charges storage battery 3b using AC power supplied from distribution board 4. Further, power measuring units 71, 72, 73 for measuring the power consumption of the dedicated loads 61, 62, 63 are further provided. Further, in the storage system A3, the relay management device 2B is different from the relay management device 2A of the second embodiment in that the relay management device 2B further includes a load information acquisition unit 2j. The same components as those of the second embodiment are denoted by the same reference numerals and the description thereof will be omitted.

  The load information acquisition unit 2 j periodically acquires measurement data (power data) of the power consumption of each of the dedicated loads 61, 62, 63 from the power measurement units 71, 72, 73, and stores the measurement data in the storage unit 2 g. . That is, the history of the power data of the dedicated loads 61, 62, 63 is stored in the storage unit 2g. The power measuring units 71, 72, 73 may create power consumption per predetermined time of each of the dedicated loads 61, 62, 63 as power data. The signal transmission path between the load information acquisition unit 2j and the power measurement units 71, 72, 73 may be either a wireless path or a wired path.

  When group identification information “G1” is allocated to the group formed of power storage devices 31, 32, and 33, control device 1 having received the DR signal is the first device in which group identification information “G1” is set. The control signal is transmitted to the relay management device 2.

  The control setting unit 2i of the relay management device 2 may estimate the power consumption of the dedicated loads 61, 62, 63 in the target period of the power reduction request instructed by the first control signal based on the history of power data. it can.

  Furthermore, based on the history of power data, the control setting unit 2i obtains the power consumption of each of the dedicated loads 61, 62, 63 estimated to consume from the current time to the start time of the target period of the power reduction request. be able to. Further, the second communication unit 2b of the relay management device 2B has a remaining capacity acquiring function, and periodically acquires information on the remaining capacity of the storage battery 3b from the power conditioners 3a of the power storage devices 31, 32, and 33, respectively. And stored in the storage unit 2g. Therefore, control setting unit 2i consumes the power consumption of dedicated loads 61, 62, 63 estimated to consume by the start time of the target period, and the remaining capacity of storage battery 3b of each of power storage devices 31, 32, 33. The remaining capacity of each storage battery 3b of power storage devices 31, 32 and 33 at the start of the target period can be estimated from the information in the above.

  Then, the control setting unit 2i determines the discharge power amount instructed to the group by the first control signal, the estimation result of the power consumption amount of the dedicated loads 61, 62, 63 in the target period, and the respective power storage devices 31, 32, 33. Based on the remaining capacity of storage battery 3b, control content instructed to each of power storage devices 31, 32, and 33 is set.

For example, it is assumed that the discharge of 10 KWh (first discharge power amount) is instructed to the group consisting of power storage devices 31, 32, and 33 by the first control signal. In this case, the control setting unit 2i sets the amount of discharged power (second amount of discharged power) instructed to each of the power storage devices 31, 32, and 33 so as to satisfy the following [condition 1] and [condition 2]. Note that, when the following [condition 1] and [condition 2] can not be simultaneously satisfied, control setting unit 2i instructs power storage devices 31, 32, and 33 to preferentially satisfy one of the conditions. Set the amount of discharge power.
[Condition 1] The total of the discharged electric energy instructed to each of the power storage devices 31, 32, and 33 matches 10 KWh.
[Condition 2] The discharged power amount instructed to the power storage device 31 is substantially equal to the power consumption amount of the dedicated load 61 in the target period and is equal to or less than the remaining capacity of the power storage device 31 at the start of the target period. The amount of discharged power instructed to power storage device 32 is substantially equal to the amount of power consumption of dedicated load 62 in the target period, and is equal to or less than the remaining capacity of power storage device 32 at the start of the target period. The amount of discharged power instructed to power storage device 33 is substantially equal to the amount of power consumption of dedicated load 63 in the target period, and is equal to or less than the remaining capacity of power storage device 33 at the start of the target period.

  In other words, condition 2 is that the storage capacity 31 capable of operating the dedicated loads 61, 62, 63 in the target period with the instructed discharge power amount and capable of covering the instructed discharge power amount is the power storage device 31. , 32 and 33 (discharged power amount 消費 consumed power amount ≦ remaining capacity).

  Therefore, control setting unit 2i secures the amount of discharged power instructed by the first control signal, and can perform the discharge operation capable of guaranteeing the operation of each of dedicated loads 61, 62, 63 as power storage devices 31, 32. , 33 can be instructed.

  Further, the control setting unit 2i performs charge control of the storage battery 3b of the power storage device 3 to be controlled individually or in groups before the target period of the power reduction request, and the storage battery 3b in a fully charged state Is preferably discharged. In this case, the possibility of simultaneously satisfying [condition 1] and [condition 2] is improved.

  The above embodiment is an example of the present invention. For this reason, the present invention is not limited to the above-described embodiment, and various other embodiments may be used according to design etc. as long as they do not deviate from the technical concept of the present invention. Of course it is possible to change.

A1, A2, A3 Stored value system 1 control device 2, 2A, 2B relay management device 2a first communication unit 2b second communication unit 2c relay control unit 2d identification information setting unit 2e operation unit 2f display unit 2g storage unit 2h test unit 2i control setting unit 2j load information acquisition unit 3 power storage device 3a power conditioner 3b storage battery 4 distribution board 5 load 61, 62, 63 dedicated load 71, 72, 73 power measuring unit 8 commercial power supply 100 wide area network 200 upper server L1 power System L2 branch circuit

Claims (10)

A relay management device that relays communication between one or more power storage devices and a control device that controls charging and discharging of the power storage devices,
A first communication unit that communicates with the control device using a first communication protocol;
A second communication unit that communicates with the power storage device using a second communication protocol;
A relay control unit that causes a signal based on a signal received by the first communication unit to be transmitted from the second communication unit, and a signal based on a signal received by the second communication unit to be transmitted from the first communication unit;
And an identification information setting unit performing group setting for setting group identification information to a group consisting of two or more storage devices, or individual setting for setting individual identification information for each storage device.
The first communication unit transmits the setting result of the group identification information and the individual identification information by the identification information setting unit to the control device.
When the first communication unit receives the first control signal to which the group identification information or the individual identification information is added, the relay control unit causes the group identification information or the individual identification information to be received from the second communication unit. A relay management device characterized by transmitting a second control signal based on the first control signal to a corresponding power storage device.   When the number of power storage devices forming the group is changed, the second communication unit acquires capacity information, which is information related to the capacity of power storage, from each of the power storage devices forming the group, and the relay control unit The relay management device according to claim 1, wherein the first communication unit is configured to transmit the sum of respective capacities of power storage devices forming the group as capacity information of the group from the first communication unit.   The relay management device according to claim 1, further comprising a control setting unit configured to set control content to be instructed to each of the plurality of power storage devices constituting the group. When the first communication unit receives the first control signal to which the group identification information is added, the control setting unit is configured to receive each of the plurality of power storage devices forming the group based on the first control signal. Set the control content to be instructed,
4. The relay according to claim 3, wherein the relay control unit causes the second communication unit to transmit a second control signal instructing the control content to each of a plurality of power storage devices constituting the group. Management device.   When discharge of the first discharge power amount is instructed to the group by the first control signal, the control setting unit divides the first discharge power amount to configure the plurality of power storage devices. 5. The relay management device according to claim 4, wherein the discharge of the second discharge power amount distributed to each is set as control content for instructing each of the plurality of power storage devices constituting the group.   The control setting unit is configured to divide a value obtained by dividing the first discharge power amount by the number of power storage devices forming the group, the second discharge power amount corresponding to each of the plurality of power storage devices forming the group. The relay management device according to claim 5, characterized in that:   The control setting unit sets the second amount of discharged power corresponding to each of the plurality of power storage devices constituting the group based on the priority of each of the plurality of power storage devices constituting the group. The relay management apparatus according to claim 5, wherein   The relay management device according to any one of claims 1 to 7, further comprising a display unit that displays information related to the power storage device acquired by the second communication unit from the power storage device. The second communication unit further includes a test unit that transmits a control signal for a test from the second communication unit to perform a test operation of the power storage device.
The relay management device according to claim 8, wherein the display unit displays a result of the test operation. One or more power storage devices, a control device that controls charging and discharging of the power storage device, and a relay management device that relays communication between the power storage device and the control device
The relay management device is
A first communication unit that communicates with the control device using a first communication protocol;
A second communication unit that communicates with the power storage device using a second communication protocol;
A relay control unit that causes a signal based on a signal received by the first communication unit to be transmitted from the second communication unit, and a signal based on a signal received by the second communication unit to be transmitted from the first communication unit;
And an identification information setting unit performing group setting for setting group identification information to a group consisting of two or more storage devices, or individual setting for setting individual identification information for each storage device.
The first communication unit transmits the setting result of the group identification information and the individual identification information by the identification information setting unit to the control device.
The control device holds the setting result of the group identification information and the individual identification information, and transmits a signal to which the group identification information or the individual identification information is added, whereby the power storage is performed via the relay management device. A storage system characterized by communicating with a device.

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