JP2012090376A - Power supply system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To improve reliability of a power supply system including a storage battery.SOLUTION: The power supply system comprises: a plurality of storage battery units 40; a power converter 28 including a bidirectional DC/AC conversion circuit or a bidirectional voltage conversion circuit; and a master controller 22 for controlling the power converter 28. The master controller 22 brings the power converter 28 into a standby state, and then brings all selection switches SW1 into an open state.

Description

  The present invention relates to a power supply system including a storage battery.

  In order to use electric power effectively, a power supply system combining a commercial power source and a storage battery has begun to be used. That is, according to the time fluctuation of the load, when the load is large, in addition to the power from the commercial power supply, the discharge power from the storage battery is supplied to the load, and when the load is small, the commercial power supply is charged to the storage battery. The power supply from is averaged over time. In addition, a photovoltaic power generation system and a fuel cell system, which have been developed in recent years, are also combined with the power supply system.

  In the power supply system, a power converter is provided. As the power converter, for example, a bidirectional cross-current conversion circuit for performing DC / AC power conversion between a storage battery that is a DC power supply and an AC power supply or an AC load, or between a storage battery and a DC power supply or a DC load. At least one bidirectional voltage conversion circuit for performing bidirectional DC / DC voltage conversion is provided. A switch is provided between the power converter and the storage battery to control connection between the power converter and the storage battery.

  In such a power supply system, when charging and discharging is performed by connecting storage batteries in parallel, power is exchanged between the storage batteries if the output voltages of the storage batteries are different. At this time, if the potential difference of the output voltage of each storage battery is large, a large charge / discharge current flows between the storage batteries having a large potential difference, which may shorten the life of the storage battery.

  In addition, when the power converter is started in a state where the storage battery is not connected, there is a risk that problems such as overloading the power converter, a switch circuit for charging and discharging, and the like may occur. Furthermore, when the capacity | capacitance of the storage battery actually connected to the power converter changes with time, it is necessary to adjust the charge / discharge amount of the storage battery via the power converter according to the change.

  The present invention includes a storage battery unit including a plurality of storage battery control units each including at least one storage battery cell and connected to a parallel connection line via a selection switch, a power source or a load, and a storage battery unit. A power converter including a cross-flow converter circuit or a voltage converter circuit, and a master controller that controls the power converter; the master controller opens all of the selection switches after placing the power converter in a standby state. It is a power supply system to be in a state.

  The present invention can improve the reliability of a power supply system including a storage battery.

It is a figure showing the whole power supply system composition in an embodiment concerning the present invention. It is a figure which shows the structure of the power supply system in embodiment which concerns on this invention. It is a figure which shows the structure of the storage battery unit in embodiment which concerns on this invention. It is a figure which shows the structure of the storage battery unit in embodiment which concerns on this invention. It is a flowchart which shows the process at the time of the discharge start in embodiment which concerns on this invention. It is a figure explaining the process at the time of the discharge start in embodiment which concerns on this invention. It is a figure explaining the process at the time of the discharge start in embodiment which concerns on this invention. It is a figure explaining the process at the time of the discharge start in embodiment which concerns on this invention. It is a flowchart which shows the process at the time of the charge start in embodiment which concerns on this invention. It is a figure explaining the process at the time of the charge start in embodiment which concerns on this invention. It is a figure which shows the whole structure of another example of the power supply system in embodiment which concerns on this invention. It is a flowchart which shows the process at the time of standby in embodiment which concerns on this invention. It is a figure which shows the structure of the switch in embodiment which concerns on this invention.

  As shown in FIG. 1, the power supply system 100 according to the embodiment of the present invention includes a power management system 102, a storage battery assembly 104, a solar battery system 106, and a system power supply 108. The power supply system 100 is used to supply power to the load 110. In FIG. 1, a thick solid line indicates a power flow, and a thin solid line indicates a signal flow.

  In the present embodiment, the solar cell system 106 and the system power supply 108 are used as power sources. The system power supply 108 is a single-phase or three-phase power supply, and may be supplied from an external power company by combining power generated by various power generation methods such as hydropower generation, nuclear power generation, and thermal power generation. it can. The solar cell system 106 can be a large-scale solar power generation system of 1 MW, for example. However, it is not limited to these, You may include other electric power sources, such as a fuel cell and a wind power generation system.

  The storage battery assembly 104 is provided to supply power corresponding to the required power of the load 110. 2 and 3, the storage battery assembly 104 includes a storage battery pack 44 in which a plurality of storage battery cells 46 are combined, a storage battery control unit 42 in which a plurality of storage battery packs 44 are combined, and a storage battery unit in which a plurality of storage battery control units 42 are combined. As shown in FIG.

  Specifically, the storage battery assembly 104 is configured as follows. In the present embodiment, as shown in FIG. 2, eight power converters 28 are provided, the storage battery assembly 104 is divided into eight, and one power converter 28 is assigned to each to perform power management. Each power converter 28 is assigned five storage battery units 40. That is, a total of 40 storage battery units 40 are provided, and each of the 5 storage battery units 40 is connected to one power converter 28. In FIG. 2, the power line is indicated by a solid line and the signal line is indicated by a broken line. A signal line between the master controller 22 and the power converter management unit 26 and a signal line between the master controller 22 and the sub-controller 24 are connected via the HUB 50.

  FIG. 3 shows one storage battery unit 40 in FIG. 2 extracted in detail. One storage battery unit 40 is configured by connecting storage battery control units (storage battery pack trains) 42 in which storage battery packs 44 are connected in series as necessary in parallel as necessary. In the example of FIG. 3, five storage battery packs 44 are connected in series to form one storage battery control unit 42, and four storage battery control units 42 are connected in parallel to form one storage battery unit 40. . In the present embodiment, one storage battery unit 40 is composed of 20 storage battery packs 44.

  Further, FIG. 3 shows an enlarged internal configuration of one storage battery pack 44. In the present embodiment, one storage battery pack 44 is configured by connecting 13 sets of 24 storage battery cells 46 that are storage battery units connected in parallel. That is, each storage battery pack 44 includes 24 × 13 = 312 storage battery cells 46.

  One storage battery unit 40 is provided with one sub-controller 24 and one switch circuit 30 respectively. As shown in FIG. 4, the switch circuit 30 is provided with one selection switch SW <b> 1 for each storage battery control unit 42. The storage battery control unit 42 is connected to the parallel connection line L1 via the selection switch SW1. The selection switch SW1 is controlled to open / close in response to an open / close control signal from the sub-controller 24. That is, the storage battery control unit 42 is a minimum unit of control when the storage battery is connected to the parallel connection line L1.

  Moreover, as shown in FIG. 4, the storage battery control unit 42 (42 (1) -42 (4)) contained in one storage battery unit 40 is connected via resistance R (R (1) -R (4)). Connected to charge / discharge line L2. Thereby, a charge / discharge current flows between the storage battery control units 42 (42 (1) to 42 (4)) via the resistors R (R (1) to R (4)), and the storage battery control unit 42 ( 42 (1) to 42 (4)) are equalized. The resistor R (R (1) to R (4)) causes a large current that adversely affects the life of the storage battery to flow between the storage battery control units 42 (42 (1) to 42 (4)). It is preferable to set a resistance value such that there is no resistance. For example, if the storage battery cell 46 is composed of a lithium ion battery and the output voltage of the storage battery control unit 42 is in the range of about 200 to 250 volts (V), the resistance R should be set to several to several hundred ohms (Ω). Is preferred. Further, a switch SW2 may be provided to charge / discharge between the storage battery control units 42 (42 (1) to 42 (4)) via the parallel connection line L1 and the charge / discharge line L2. The storage battery control units 42 (42 (1) to 42 (4)) are connected to the parallel connection line L1 and the charge / discharge line L2 via the breakers BR (BR (1) to BR (4)), respectively. It is preferable to configure. The breaker BR is provided to protect the storage battery control unit 42 by separating the storage battery control unit 42 and the circuit when the charge / discharge current to the storage battery control unit 42 exceeds a predetermined cutoff reference current value.

  The storage battery unit 40 is provided with a storage battery current sensor 52. The storage battery current sensor 52 is provided for each storage battery control unit 42 or each storage battery pack. The storage battery current sensor 52 detects a current for each storage battery control unit 42 and a current for each storage battery pack 44. The storage battery unit 40 is provided with a storage battery voltage sensor 54. The storage battery voltage sensor 54 is a parallel assembly of 13 sets of storage battery cells 46 connected in series for each storage battery control unit 42, each storage battery pack 44 or storage battery pack 44 (a set of 24 storage battery cells 46 entrusted in parallel connection). Body). Thereby, the voltage for every storage battery control unit 42, the voltage for every storage battery pack 44, and the voltage between terminals of the parallel assembly of the storage battery cells 46 are detected. In FIG. 3, only one storage battery current sensor 52 and storage battery voltage sensor 54 are illustrated to simplify the drawing. The temperature of the storage battery pack 44 is detected by the temperature sensor 56 as the pack temperature. A plurality of temperature sensors 56 may be provided for each storage battery pack 44. These data are acquired by the sub-controller 24. The sub-controller 24 uses these data and a charge / discharge state (SOC: State Of Charge) calculated from these data as unit state data S3 and S6 indicating the state of each storage battery unit 40, and the master controller 22 and the storage battery power management device 12. Output to. Moreover, when the malfunction has arisen in the storage battery unit 40 which comprises the storage battery assembly 104, the sub controller 24 includes the information for specifying the malfunctioning storage battery unit 40 in unit state data S3, S6. To send.

  Further, the sub-controller 24 receives a switch state signal indicating the open / closed state of the switch from the selection switch SW1, switch SW2, unit switch SW3, SW4 included in the storage battery unit 40, and includes such information in the unit state data S3 as a master. Output to the controller 22. It is preferable that the switch state signal can reliably determine at least the actual open / close state of each switch. For example, when the switch is an FET, it is preferable to directly detect the gate voltage of the FET. The use of the switch status signal will be described later.

  Note that the number of combinations of the storage battery cell 46, the storage battery pack 44, the storage battery control unit 42, and the storage battery unit 40 may be appropriately changed according to the specifications of the power supply system 100. Moreover, although a lithium ion battery can be used as a storage battery, you may apply other secondary batteries. For example, a nickel metal hydride battery, a nickel cadmium battery, a manganese battery, or the like may be applied.

  The power supply system 100 is provided to supply power to a load 110 including general lighting, general air conditioning, kitchen appliances, display cases, air conditioning equipment, and the like of a factory facility.

  The load 110 is provided with a power management device 110a. The power management device 110a includes a load power management device 10, a storage battery power management device 12, and a total power monitoring device 14.

  The load power management apparatus 10 acquires load side information data S9 indicating the required power of the load 110. The load-side information data S9 includes the total required power requirement amount of the load 110 necessary for the system controller 20 to be described later to set the overall charge / discharge control command S1. As shown in FIG. 1, when the load 110 is divided into four systems, the load power management device 10 is internally an aggregate of four systems of load power management devices.

  The storage battery power management device 12 includes unit state data S6 indicating the state of each storage battery unit 40 included in the storage battery assembly 104 and power converter management data S7 indicating each state of the power converter 28 included in the power supply system 100. Receive. The storage battery power management device 12 transfers these pieces of information to the total power monitoring device 14. Unit state data S6 includes information used to generate overall charge / discharge control command S1. In the unit state data S6, as described above, there is a defect in any of the data such as the voltage, temperature, current, and SOC of the storage battery constituting the storage battery assembly 104 and the storage battery unit 40 constituting the storage battery assembly 104. Contains information indicating these defects. Moreover, the information regarding the malfunction of the power converter 28 related to the setting of the whole charge / discharge control command S1 is included in the power converter management data S7. For example, when any of the power converters 28 included in the storage battery assembly 104 has a problem such as a failure, information for specifying the power converter 28 in which the problem has occurred is included.

  The total power monitoring device 14 receives the load side information data S9 from the load power management device 10 and the unit state data S6 and the power converter management data S7 from the storage battery power management device 12, and is necessary for charge / discharge control from these information. Extract data. The total power monitoring device 14 outputs the extracted information to the system controller 20 as a system management signal S8. The system management signal S8 is transmitted at a cycle of once every 1 s, for example.

  As shown in FIG. 1, the power management system 102 includes a system controller 20, a master controller 22, a sub-controller 24, a power converter management unit 26, and a power converter 28. The power management system 102 is configured as a hierarchical control system, and control is hierarchized from the upper level to the lower level to the system controller 20, the master controller 22, the sub controller 24, and the power converter management unit 26. .

  The system controller 20 has a function of performing integrated power management of the power supply system 100. The master controller 22 is a control device that receives the entire charge / discharge control command S <b> 1 from the system controller 20 and performs charge / discharge control for the entire storage battery assembly 104. The power converter management unit 26 controls processing such as power conversion and voltage conversion in each of the power converters 28 included in the power supply system 100. The sub-controller 24 is provided for each storage battery unit 40 included in the storage battery assembly 104 and controls charging / discharging in each storage battery unit 40. Hereinafter, these components will be described.

  The system controller 20 receives a system management signal S8 including the load side information data S9 and the storage battery information signal unit state data S6 from the power management apparatus 110a, and is a charge / discharge control command for the entire power supply system 100 based on these information. An overall charge / discharge control command S1 is generated and output.

  Specifically, the system controller 20 considers the state of the storage battery unit 40 and the power converter 28, and changes the charge / discharge state that satisfies the overall required power requirement of the load 110 from the charge / discharge capacity of the storage battery assembly 104. This is obtained and transmitted to the master controller 22 as an overall charge / discharge control command S1. Preferably, the system controller 20 also considers information regarding the charge / discharge state of the storage battery unit 40 connected to the power converter 28 in which the failure has occurred and the charge / discharge state of the storage battery unit 40 in which the failure has occurred. Then, the charging / discharging state satisfying the total required power requirement of the load 110 is obtained from the charging / discharging state of the storage battery assembly 104, and this is transmitted to the master controller 22 as the entire charging / discharging control command S1.

  In the overall charge / discharge control command S1, the charge / discharge conditions are indicated by the electric energy and the time, for example, “Charge at XX kW for YY seconds”. In addition to this, it may be possible to specify a charge upper limit voltage and “charge with XX kW until the voltage reaches ZZV”, or specify a discharge lower limit voltage and “discharge to ZZV”, and specify the SOC. It is also possible to command charging / discharging. Here, the SOC is a value in which the SOC (degree of charge) in a state where the electric power is stored at a maximum is 100 in a practical range, and the SOC (degree of charge) in a state where the electric power is stored at a minimum is 0. The SOC (degree of charge) in each storage state of electric power is expressed as a percentage based on that.

  Further, when the discharge by the storage battery assembly 104 reaches the lower limit of discharge or when the charge reaches the upper limit of charge, the overall charge / discharge control command S1 is “set the charge / discharge to the standby state (or at 0 kW). Charge / discharge) ”and the like.

  Since the overall charge / discharge control command S1 is transmitted irregularly only when necessary, it may occur that the overall charge / discharge control command S1 is not transmitted for a considerably long time in some cases. In such a case, the master controller 22 that receives the overall charge / discharge control command S1 may not be able to determine whether the system controller 20 is active and in operation or inactive and inactive. Therefore, a confirmation signal S2 for confirming whether or not the system controller 20 is operating is transmitted from the master controller 22 to the system controller 20 at an appropriate period. The system controller 20 responds with a response signal during operation. The master controller 22 determines that the system controller 20 is operating if a response signal is returned from the system controller 20, and determines that the system controller 20 is not operating if no response signal is returned from the system controller 20. can do. An appropriate period may be 10 minutes, for example.

  The master controller 22 is a control device having a function of receiving the overall charge / discharge control command S1 from the system controller 20 and transmitting the aggregate charge / discharge control command S5 for each power converter 28 to the power converter management unit 26.

  The master controller 22 includes power converter management data S4, which is status data of the power converter 28 from the power converter management unit 26, and each of the sub-controllers 24 provided in each storage battery unit 40 included in the storage battery assembly 104. Unit state data S3 indicating the state of the storage battery unit 40 is received. Based on the received unit state data S3, the master controller 22 activates each power converter 28, gives a start instruction command to instruct each power converter 28 to wait, and stops each power converter 28. The assembly charge / discharge control instruction S5 including any one of the stop instruction instructions is transmitted to the power converter management unit 26. The aggregate charge / discharge control command S5 includes target charge / discharge power for charge / discharge control by each power converter 28 as necessary. Further, the master controller 22 determines whether or not the overall charge / discharge control command S1 transmitted from the system controller 20 can be executed based on the power converter management data S4 and the unit state data S3, and based on the determination result. The assembly charge / discharge control command S5 is transmitted to the power converter management unit 26. This determination can be made, for example, by applying the unit state data S3 or the like to a predetermined conditional expression. If the overall charge / discharge control command S1 cannot be executed due to power converter capacity restrictions or safety constraints, the charge / discharge control command S5 is converted to power by suppressing the charge / discharge amount to an executable one. Sent to the instrument management unit. Or it is good also as control which does not transmit aggregate charging / discharging control instruction | command S5. Moreover, when the overall charge / discharge control command S1 cannot be executed as commanded, the result may be transmitted to the storage battery power management device 12.

  The assembly charge / discharge control command S5 is transmitted / received at a cycle of 100 ms, and the power converter management data S4 and the unit state data S3 are transmitted / received at a cycle of 1 s, for example. Specific charge / discharge management processing by the master controller 22 will be described later.

  In addition, the master controller 22 transmits data having the same content as the power converter management data S4 received from the power converter management unit 26 to the storage battery power management apparatus 12 as power converter management data S7. Since the master controller 22 exclusively performs short-term (about 1 second) monitoring / control of charging / discharging, the storage battery power management device 12 and the total power monitoring device 14 may be managed and monitored in a longer cycle. Therefore, in order to reduce the processing load or communication load of the storage battery power management device 12 and the total power monitoring device 14, the power converter management data S7 is transmitted at a transmission cycle longer than the transmission cycle of the power converter management data S4. It may be a thing. For example, when the power converter management data S4 is transmitted every second, the power converter management data S7 may be transmitted every 10 seconds.

  In this case, the power converter management data S7 includes information for 10 times of the power converter management data S4. Of course, other transmission periods may be used, and the transmission periods of the power converter management data S4 and the power converter management data S7 may be the same. In the present embodiment, the power converter management data S7 is indirectly transmitted from the power converter management unit 26 to the power management apparatus 110a including the storage battery power management apparatus 12 via the master controller 22, but the power conversion You may transmit directly to the power management apparatus 110a containing the storage battery power management apparatus 12 from the storage device management part 26. FIG.

  The sub-controller 24 is provided for each storage battery unit 40 and controls opening and closing of switches included in the switch circuit 30 provided in each storage battery unit 40 according to the state of each storage battery unit 40. As will be described later, when the switching control of the switch included in the switch circuit 30 is different between discharging and charging, which of the discharging process or the charging process is executed from the master controller 22 to the sub-controller 24? It is preferable to send information about. As a result, the sub-controller 24 can independently perform opening / closing control of the switches of the switch circuit 30 in an order suitable for each of the discharging process and the charging process.

  When the power supply (not shown) is turned on, the sub-controller 24 closes the unit switches SW3 and SW4 of the switch circuit 30 shown in FIG. 4 and connects the storage battery unit 40 to the power converter 28. The timing for closing the unit switches SW3 and SW4 may be after connecting a storage battery control unit 42 described later to the parallel connection line L1.

  Here, the sub-controller 24 includes a current value detected by the storage battery current sensor 52 provided in each storage battery unit 40, a voltage value detected by the storage battery voltage sensor 54, and a temperature sensor 56 provided in each storage battery unit 40. The state of the storage battery unit 40 is determined based on the detected temperature. The sub-controller 24 disconnects the connection between the storage battery unit 40 and the power converter 28 by opening the unit switches SW3 and SW4 of the switch circuit 30 when the storage battery unit 40 has a problem.

  The sub-controller 24 detects the current value detected by the storage battery current sensor 52 provided in each storage battery unit 40, the voltage value detected by the storage battery voltage sensor 54, and the temperature sensor 56 provided in each storage battery unit 40. The state of the storage battery pack 44 and the storage battery control unit 42 is determined on the basis of the detected temperature and the reference voltage detected by the parallel connection line voltage sensor 60 provided in the parallel connection line L1, and the storage battery control unit is determined according to the determination result. Open / close control of the selection switch SW1 (SW1 (1) to SW1 (4)) corresponding to 42 is performed.

  For example, the sub-controller 24 detects the current value detected by the storage battery current sensor 52 provided in each storage battery unit 40, the voltage value detected by the storage battery voltage sensor 54, and the temperature sensor 56 provided in each storage battery unit 40. It is determined whether or not a problem has occurred in the state of the storage battery pack 44 or the storage battery control unit 42 based on the detected temperature and the reference voltage detected by the parallel connection line voltage sensor 60 provided in the parallel connection line L1. When it is determined that a problem has occurred, the sub-controller 24 performs a process of disconnecting the storage battery control unit 42 including the storage battery pack 44 having the problem from the parallel connection line L1. Specifically, the selection switch SW1 (SW1 (1) to SW1 (4)) corresponding to the storage battery control unit 42 including the storage battery pack 44 in which a problem has occurred is opened. Further, the sub-controller 24 transmits information indicating the malfunction of the storage battery pack 44 and the storage battery control unit 42 to the master controller 22 and the storage battery power management device 12 as unit state data S3 and S6.

  When the current detected by the storage battery current sensor 52 falls outside the threshold range calculated from the predetermined conditional expression, the cell voltage detected by the storage battery voltage sensor 54 falls outside the predetermined threshold range. When the pack temperature detected by the temperature sensor 56 is out of a predetermined threshold range, it can be compared with a predetermined condition.

  At the start of charging / discharging of the storage battery assembly 104, the selection switches SW1 (SW1 (1) to SW1 (4) corresponding to the storage battery control unit 42 based on the voltage value detected for each storage battery control unit 42 by the storage battery voltage sensor 54. )) Open / close control is performed. This process will be described later.

  Moreover, the sub controller 24 transmits the information which shows the malfunction of the storage battery unit 40 to the master controller 22 and the storage battery power management apparatus 12 as unit state data S3, S6 as mentioned above.

  Here, the unit state data S6 may be transmitted at a transmission cycle longer than the transmission cycle of the unit state data S3. The reason why the unit state data S6 is set to be longer than the unit state data S3 is to reduce the processing load or communication load of the storage battery power management device 12 and the total power monitoring device 14. For example, when the unit state data S3 is transmitted every second, the unit state data S6 may be transmitted every 10 seconds. In this case, the unit state data S6 includes information for 10 times of the unit state data S3.

  Of course, other transmission periods may be used, and the transmission periods of the unit state data S3 and the unit state data S6 may be the same. In the present embodiment, the unit state data S6 is directly transmitted from the sub controller 24 to the power management apparatus 110a including the storage battery power management apparatus 12, but the storage battery power management is performed from the sub controller 24 via the master controller 22. You may transmit indirectly to the power management apparatus 110a containing the apparatus 12. FIG.

  The power converter management unit 26 receives the assembly charge / discharge control command S5 from the master controller 22 and controls each of the power converters 28 to be controlled. In power supply system 100 according to the present embodiment, as shown in FIG. 2, there are eight power converters 28 to be controlled by power converter management unit 26. However, the present invention is not limited to this, and the number of power converters 28 may be changed as appropriate. The management process of the power converter 28 in the power converter management unit 26 will be described later.

  The power converter 28 performs power conversion between the AC power of the system power supply 108 and the DC power of the storage battery assembly 104, voltage conversion between the DC voltage of the solar battery system 106 and the DC voltage of the storage battery assembly 104, and the storage battery. It has a function of performing power conversion between the DC power of the assembly 104 and the AC power of the load 110, voltage conversion between the DC voltage of the storage battery assembly 104 and the DC voltage of the load 110, and the like. Specifically, a bidirectional cross flow conversion circuit, a bidirectional voltage conversion circuit, and the like are configured as necessary.

  In the above description, the selection switch SW1, the switch SW2, and the unit switches SW3 and SW4 in FIG. 4 are shown as being based on one FET transistor. However, as shown in FIG. It is preferable that they are connected in series so that is in the opposite direction. In this case, opening / closing control is performed so that two FET transistors connected in series are simultaneously opened or closed. With such a switch configuration, it is possible to prevent an unexpected current from flowing due to the parasitic diode even though the FET transistor is opened.

  As described above, the system controller 20 obtains the entire charge / discharge state of the storage battery assembly 104 that satisfies the total required power requirement of the load 110 and sets it as the overall charge / discharge control command S1. And in the master controller 22, for the specific control of each power converter 28 in consideration of the power converter 28 and the storage battery unit 40 in which a failure has occurred so as to satisfy the charge / discharge control command in the overall charge / discharge control command S1. The assembly charge / discharge control command S <b> 5 is generated, and each power converter 28 is controlled by the power converter management unit 26 lower than the master controller 22. At this time, the power converter management unit 26 performs a process of disconnecting the power converter 28 and the storage battery unit 40 connected thereto without being directly controlled by the host system controller 20 and the master controller 22. The sub-controller 24 controls connection / disconnection of the storage battery control unit 42 included in each storage battery unit 40 without direct control by the host system controller 20 and the master controller 22. Thus, by performing hierarchical control, even if a malfunction occurs in a part of the power converter 28 or the storage battery unit 40, the storage battery assembly 104 looks as if it is a single battery as viewed from the system controller 20. Can be handled. Further, it is possible to reduce the processing load of the higher-order control system and flexibly cope with changes in the system configuration.

<Treatment during charging / discharging>
Hereinafter, a process of discharging the storage battery assembly 104 from the storage battery assembly 104 to the load 110 and charging the storage battery assembly 104 from the solar cell system 106 or the system power supply 108 will be described. First, the discharge process from the start of discharge will be described, and then the charge process from the start of charging will be described.

  The process at the time of discharge is performed according to the flowchart shown in FIG. Before the start of discharging, the power of all the storage battery units 40 included in the power supply system 100 is turned off (that is, the sub-controller 24 and the switch circuit 30 of the storage battery unit 40 are in a non-operating state). It is assumed that the included selection switches SW1, SW2 and unit switches SW3, SW4 are open. In the following processing at the time of discharging, the switches corresponding to the defective storage battery pack 44 and the storage battery control unit 42 are maintained in the closed state.

  In the following description, the voltage detected by each storage battery voltage sensor 54 will be described as an output voltage detected for each storage battery control unit 42. Of course, a value obtained by summing the output voltages of the storage battery packs 44 constituting each storage battery control unit 42 or a value obtained by summing the output voltages detected from each parallel connection body of the storage battery cells 46 can also be used. Further, in the following description, an example in which the output voltage detected for each storage battery control unit 42 is used as it is is shown. However, in order to perform connection control of the storage battery unit 40 with high accuracy, each storage battery control unit 42 is opened. The output voltage should be used. The output voltage at the time of opening excludes the influence of voltage drop or voltage rise caused by the internal resistance included in the storage battery control unit 42 and the current flowing through the storage battery control unit 42. The internal resistance included in the storage battery control unit 42 changes with a predetermined relationship depending on temperature, current value, and the like. Therefore, the voltage drop or voltage rise caused by the internal resistance is estimated based on the detected voltage value of the storage battery control unit 42 by the storage battery voltage sensor 54, the detected current value of the storage battery control unit 42 by the storage battery current sensor 52, the detected temperature by the temperature sensor 56, and the like. Therefore, it is possible to calculate the open output voltage for each storage battery control unit 42.

  In step ST10, any one of the storage battery units 40 assigned to each power converter 28 is turned on (that is, the sub-controller 24 and the switch circuit 30 of the storage battery unit 40 are in an operating state). Depending on whether or not the load 110 is a DC load or an AC load, the sub-controller 24 of the storage battery unit 40 whose power is turned on determines one or both of the unit switches SW3 and SW4 included in the storage battery unit 40. Is closed and connected to the power converter 28. Thereby, one storage battery unit 40 is connected to each power converter 28.

  Here, the power supply of the storage battery unit 40 may be manually turned on by the user, or the power supply of each storage battery unit 40 may be automatically turned on in order by the master controller 22 or the like according to a predetermined sequence. However, it is preferable that the power of the other storage battery units 40 is sequentially turned on after each step ST12 in the following processing is completed for each storage battery unit 40 whose power is already turned on.

  In step ST12, the storage battery control unit 42 having the highest output voltage is extracted from the storage battery control units 42 included in the storage battery unit 40 that is turned on, and the selection switch SW1 corresponding to the extracted storage battery control unit 42 is set. Outputs an open / close control signal for closing.

For example, in the case of the configuration shown in FIG. 4, the sub-controller 24 uses the voltage values detected by the storage battery voltage sensors 54 (1) to 54 (4) provided in the storage battery control units 42 (1) to 42 (4). To obtain the output voltage of each of the storage battery control units 42 (1) to 42 (4). The sub-controller 24 selects the storage battery control unit 42 (1) corresponding to the storage battery control unit 42 (1) if the storage battery control unit 42 (1) has the highest output voltage among the storage battery control units 42 (1) to 42 (4). An open / close control signal for closing the switch SW1 (1) is output to the selection switch SW1 (1).
Thereby, the storage battery control unit 42 (1) having the highest output voltage among the storage battery control units 42 included in the storage battery unit 40 that is turned on is connected to the parallel connection line L1, and the reference voltage of the parallel connection line L1 is It is determined.

  In step ST14, opening / closing control of the selection switch SW1 corresponding to the storage battery control unit 42 is performed based on the difference between the output voltage of the storage battery control unit 42 included in the storage battery unit 40 that is turned on and the reference voltage of the parallel connection line L1. Do.

  When the selection switch SW1 (1) corresponding to the storage battery control unit 42 (1) is closed in step ST12, the sub-controller 24 sets the storage battery voltage provided in the storage battery control units 42 (2) to 42 (4). Whether the difference between the output voltage detected by the sensors 54 (2) to 54 (4) and the reference voltage of the parallel connection line detected by the parallel connection line voltage sensor 60 is within a predetermined connection voltage range. Determine whether. Then, the sub-controller 24 closes only the selection switches SW1 (2) to SW1 (4) corresponding to the storage battery control units 42 (2) to 42 (4) whose voltage values are within the connection voltage range. Outputs an open / close control signal.

  For example, as shown in FIG. 6, if the output voltage of the storage battery control units 42 (2) and 42 (3) is within the connection voltage range, the sub-controller 24 closes the selection switches SW1 (2) and SW1 (3). Outputs an open / close control signal to enter a state.

  Here, the connection voltage range is set as a predetermined voltage range with respect to the reference voltage. It is preferable that the connection voltage range is set so that the mutual currents that flow when the storage battery control unit 42 is connected to the parallel connection line L <b> 1 have values that do not have a significant adverse effect on the storage battery control unit 42. For example, the connection voltage range can be ± 5 volts (V).

  In addition, when the connection voltage range is divided into an upper limit range above the reference voltage and a lower limit range below the reference voltage, it is also preferable to set the upper limit range and the lower limit range to different voltage widths. Here, it is more preferable to set the upper limit range to be larger than the lower limit range. For example, when the upper limit range is set to + 3V with respect to the reference voltage, it is preferable to set the lower limit range to −2V with respect to the reference voltage.

  In general, a storage battery is more durable against excessive charge and discharge in a discharged state in which current flows than in a charged state in which current flows. Therefore, even if the upper limit range of the connection voltage range is set wider than the lower limit range, the storage battery control units 42 higher than the reference voltage are connected to the parallel connection line L1, and only discharge is performed from these storage battery control units 42. Therefore, the possibility of causing deterioration of the characteristics of the storage battery control unit 42 is reduced.

  The process of step ST14 is also performed by turning on the power of other storage battery units 40 that are not yet turned on among the storage battery units 40 assigned to each power converter 28. At this time, the reference voltage of the parallel connection line L1 is determined by the storage battery control unit 42 connected to the parallel connection line L1 from the storage battery unit 40 that is first turned on. Therefore, for the storage battery units 40 whose power is turned on for the second and subsequent times, the storage battery control units 42 are sequentially changed based on the difference between the output voltage of each storage battery control unit 42 and the reference voltage of the parallel connection line L1 that has already been determined. Open / close control of the corresponding selection switch SW1 is performed.

  Moreover, the process of step ST14 is performed at any time by the sub-controller 24 provided in each storage battery unit 40 while discharging from the storage battery assembly 104 to the load 110. That is, if discharge is performed from the storage battery control units 42 connected to the parallel connection line L1, and the output voltage of those storage battery control units 42 decreases, the reference voltage of the parallel connection line L1 decreases accordingly. The selection switch SW1 corresponding to the storage battery control unit 42 that has entered the connection voltage range is closed at any time. Such processing is similarly performed if there is a storage battery unit 40 connected to the power converter 28 other than the storage battery unit 40 connected to the power converter 28 first.

  In addition, as described above, charging / discharging between the storage battery control units 42 (42 (1) to 42 (4)) also via the resistors R (R (1) to R (4)) included in the switch circuit 30. Is done. This also reduces the difference in output voltage between the storage battery control units 42 (42 (1) to 42 (4)), so that the selection switch SW1 corresponding to the storage battery control unit 42 that has newly entered the connection voltage range is provided. Closed at any time.

  Thus, by connecting the storage battery control unit 42 having the output voltage within the connection voltage range to the parallel connection line L1, it is possible to prevent excessive charge / discharge between the storage battery control units 42 from occurring. Further, in step ST12, the storage battery control unit 42 having the highest output voltage among the storage battery control units 42 included in the storage battery unit 40 is first connected to the parallel connection line L1, so that the load is sequentially applied from the storage battery control unit 42 having the largest SOC. 110, the output voltage can be lowered by discharging from the storage battery control unit 42 having a high output voltage, and the other storage battery control units 42 can be connected to the parallel connection line L1 in order.

  In step ST16, the master controller 22 performs the activation process of the power converter 28. The sub-controller 24 receives a switch state signal indicating an actual open / close state from the selection switch SW1 under control, and transmits the switch state signal to the master controller 22 by including it in the unit state data S3. When the master controller 22 receives the unit state data S3 from each of the sub-controllers 24, the power to which a predetermined number or more of the storage battery control units 42 are connected among the power converters 28 included in the power supply system 100 based on the switch state signal. An assembly charge / discharge control command S5 including an activation instruction command for activating the converter 28 is generated and transmitted to the power converter management unit 26. The power converter management unit 26 activates the power converter 28 that is instructed to be activated by the activation instruction command, and starts power conversion and voltage conversion.

  Here, it is preferable that the predetermined number is a number that does not cause a problem even if discharge through each power converter 28 is started. For example, the predetermined number can be 1. In this case, the power converter 28 to which at least one storage battery control unit 42 is connected is activated.

  The master controller 22 generates an aggregate charge / discharge control command S5 for controlling each power converter 28 based on the overall charge / discharge control command S1 from the system controller 20.

  The overall charge / discharge control command S <b> 1 is a command value indicating the overall charge / discharge amount of the storage battery assembly 104 transmitted to the master controller 22. The aggregate charge / discharge control command S5 is a target charge / discharge power obtained by disassembling the command value in the overall charge / discharge control command S1 for each power converter 28. Therefore, when all the power converters 28 are not defective and an equal number of storage battery control units 42 are connected, the assembly charge / discharge control command S5 is the total charge / discharge control command S1 by the number of power converters 28. Divided value. For example, as shown in FIG. 2, when eight power converters 28 are provided for the power converter management unit 26, the entire charge / discharge control command S <b> 1 is “discharge at 320 kW for 1800 seconds”. As shown in FIG. 7, the assembly charge / discharge control command S5 indicates that “the first power converter 28 (1) is discharged at 40 kW and the second power converter 28 (2) is discharged at 40 kW. The eighth power converter 28 (8) is discharged at 40 kW.

  On the other hand, when the number of storage battery control units 42 actually connected to each power converter 28 is different, the aggregate charge / discharge control command in which the discharge power allocated to each power converter 28 is changed according to the number. S5 is generated. For example, as shown in FIG. 8, 20 storage battery control units 42 are actually connected to the first to seventh power converters 28, and 15 storage battery controls are connected to the eighth power converter 28. Assume that the unit 42 is actually connected (in the figure, the storage battery pack 44 included in the storage battery control unit 42 that is not connected is hatched). In this case, assuming that the overall charge / discharge control command S1 is “discharge at 320 kW for 1800 seconds”, the “first to first” are set in accordance with the ratio of the number of storage battery control units 42 connected to each power converter 28. 7 power converter 28 is discharged at 41.3 kW, and the eighth power converter 28 is discharged at 31 kW.

  The master controller 22 updates the aggregate charge / discharge control command S5 each time the number of storage battery control units 42 connected to each power converter 28 is changed in step ST14.

  Further, when it is transmitted by the power converter management data S4 that there is a malfunction in any of the power converters 28 controlled by the power converter management unit 26, a part of the entire charge / discharge control command S1 is discharged. The assembly charge / discharge control command S5 with the content restricted is transmitted to the power converter management unit 26. Specifically, the power converter management data S4 includes information indicating a malfunction of the power converter 28, and the unit state data S3 includes information indicating a malfunction of the storage battery unit 40. For the other power converters 28 excluding the power converter 28 in which the failure has occurred, the master controller 22 has the other storage battery units 40 except for the storage battery unit 40 in which the failure has occurred in the storage battery units 40 connected thereto. In accordance with the ratio of the numbers, an assembly charge / discharge control command S5 for controlling each power converter 28 is generated so that the discharge state required by the overall charge / discharge control command S1 is satisfied, and the power converter management unit 26.

  The power converter management unit 26 controls power conversion and voltage conversion in each power converter 28 when discharging from the storage battery assembly 104 to the load 110 in accordance with the assembly charge / discharge control command S5. In addition, when any of the power converters 28 under the control of the power converter management unit 26 is defective, or when a discharge stop instruction command or a standby instruction command is output from the master controller 22 Then, the operation of the malfunctioning power converter 28 is stopped or in a standby state, and information indicating the malfunction of the power converter 28 is transmitted to the master controller 22 as power converter management data S4.

  Such processing can prevent the power converter 28 not connected to the storage battery control unit 42 from being activated. In addition, each power converter 28 can be controlled so as to have a discharge power corresponding to the number of storage battery control units 42 actually connected to each activated power converter 28. Thereby, the current flowing through the storage battery control unit 42 connected to the power converter 28 can be distributed substantially evenly.

  In the process at the time of discharging, in step ST10, the unit switches SW3 and SW4 of the arbitrary storage battery unit 40 are first closed and connected to the power converter 28. However, all the units assigned to one power converter 28 are connected. The storage battery unit 40 including the storage battery control unit 42 having the highest output voltage among the storage battery control units 42 may be connected to the power converter 28 first.

  In this case, the output voltage value of the storage battery control unit 42 included in each storage battery unit 40 can be included in the unit state data S3 and output to the master controller 22 via the sub-controller 24.

  In the master controller 22, the storage battery unit 40 including the storage battery control unit 42 having the highest output voltage among all the storage battery control units 42 assigned to each power converter 28 is specified, and the power source of the storage battery unit 40 is first turned on. turn on. And the storage battery control unit 42 with the highest output voltage among the storage battery control units 42 is connected to the parallel connection line L1 first. In this case, it is preferable that the master controller 22 is configured to be able to control on / off of the power source of the power converter 28 via the power converter management unit 26. Subsequent processing is performed in the same manner as steps ST10 to ST16.

  Thus, the storage battery control unit 42 having the highest output voltage among all the storage battery control units 42 assigned to each power converter 28 can be connected to the parallel connection line L1 first. Therefore, each power converter 28 can be connected to the load 110 in order from the storage battery control unit 42 having a large SOC, and other storage battery control units according to the decrease in the output voltage due to the discharge from the storage battery control unit 42 to the load 110. 42 can also be sequentially connected to the parallel connection line L1.

  Such control can also be applied during charging. At the time of charging, processing is performed according to the flowchart shown in FIG. Before the start of charging, all the storage battery units 40 included in the storage battery assembly 104 are turned off, and the selection switches SW1, SW2 and unit switches SW3, SW4 included in each storage battery unit 40 are in an open state. It is assumed that Even in the following charging process, the switches corresponding to the defective storage battery pack 44 and the storage battery control unit 42 are kept closed.

  In step ST20, the power source of any one of the storage battery units 40 assigned to each power converter 28 is turned on. The sub-controller 24 of the storage battery unit 40 that is turned on depends on whether the power source is a DC power supply such as the solar battery system 106 or an AC power supply such as the system power supply 108. Either or both of the unit switches SW3 and SW4 included in the unit 40 are closed and connected to the power converter 28. Thereby, one storage battery unit 40 is connected to each power converter 28. This process can be performed in the same manner as in step ST10.

  In step ST22, the storage battery control unit 42 having the lowest output voltage is extracted from the storage battery control units 42 included in the storage battery unit 40 that is turned on, and the selection switch SW1 corresponding to the extracted storage battery control unit 42 is set. Outputs an open / close control signal for closing.

  For example, in the case of the configuration shown in FIG. 4, the sub-controller 24 uses the voltage values detected by the storage battery voltage sensors 54 (1) to 54 (4) provided in the storage battery control units 42 (1) to 42 (4). To obtain the output voltage of each of the storage battery control units 42 (1) to 42 (4). The sub-controller 24 selects the storage battery control unit 42 (1) corresponding to the storage battery control unit 42 (1) if the storage battery control unit 42 (1) has the lowest output voltage among the storage battery control units 42 (1) to 42 (4). An open / close control signal for closing the switch SW1 (1) is output to the selection switch SW1 (1). Thereby, the storage battery control unit 42 (1) having the lowest output voltage among the storage battery control units 42 included in the storage battery unit 40 that is turned on is connected to the parallel connection line L1, and the reference voltage of the parallel connection line L1 is It is determined.

  In step ST24, the open / close control of the selection switch SW1 corresponding to the storage battery control unit 42 is performed based on the difference between the output voltage of the storage battery control unit 42 included in the storage battery unit 40 that is turned on and the reference voltage of the parallel connection line L1. Do.

  When the selection switch SW1 (1) corresponding to the storage battery control unit 42 (1) is closed in step ST22, the sub-controller 24 sets the storage battery voltage provided in the storage battery control units 42 (2) to 42 (4). Whether or not the difference between the output voltage detected by the sensors 54 (2) to 54 (4) and the reference voltage of the parallel connection line L1 detected by the parallel connection line voltage sensor 60 is within a predetermined connection voltage range. Determine whether. Then, the sub-controller 24 closes only the selection switches SW1 (2) to SW1 (4) corresponding to the storage battery control units 42 (2) to 42 (4) whose voltage values are within the connection voltage range. Outputs an open / close control signal.

  For example, as shown in FIG. 10, if the output voltage of the storage battery control units 42 (2) and 42 (3) is within the connection voltage range, the sub-controller 24 closes the selection switches SW1 (2) and SW1 (3). Outputs an open / close control signal to enter a state. Here, the connection voltage range can be set based on the same concept as in the case of discharging.

  The process of step ST24 is performed at any time by the sub-controller 24 provided in each storage battery unit 40 while charging the storage battery assembly 104 from the power source. That is, if the storage battery control unit 42 connected to the parallel connection line L1 is charged and the output voltage of those storage battery control units 42 increases, the reference voltage of the parallel connection line L1 increases accordingly. The selection switch SW1 corresponding to the storage battery control unit 42 that has entered the connection voltage range is closed at any time. Such processing is similarly performed if there is a storage battery unit 40 connected to the power converter 28 other than the storage battery unit 40 connected to the power converter 28 first.

  In addition, as described above, charging / discharging between the storage battery control units 42 (42 (1) to 42 (4)) also via the resistors R (R (1) to R (4)) included in the switch circuit 30. Is done. This also reduces the difference in output voltage between the storage battery control units 42 (42 (1) to 42 (4)), so that the selection switch SW1 corresponding to the storage battery control unit 42 that has newly entered the connection voltage range is provided. Closed at any time.

  Thus, by connecting the storage battery control unit 42 having the output voltage within the connection voltage range to the parallel connection line L1, it is possible to prevent excessive charge / discharge between the storage battery control units 42 from occurring. Moreover, in step ST22, the storage battery control unit 42 having the lowest output voltage among the storage battery control units 42 included in the storage battery unit 40 is connected to the parallel connection line L1 first, thereby charging in order from the storage battery control unit 42 having the smallest SOC. It is possible to increase the output voltage by charging the storage battery control unit 42 with a low output voltage, and the other storage battery control units 42 can be connected to the parallel connection line L1 in order.

  In step ST26, the same process as in step ST16 is performed. That is, when the master controller 22 receives the unit status data S3 from each sub-controller 24, a predetermined number or more of the storage battery control units 42 of the power converters 28 included in the power supply system 100 are connected based on the switch status signal. The assembly charge / discharge control command S5 including the start instruction command for starting the power converter 28 is generated and transmitted to the power converter management unit 26. The power converter management unit 26 activates the power converter 28 that is instructed to be activated by the activation instruction command, and starts power conversion and voltage conversion.

  Moreover, the master controller 22 produces | generates the assembly charging / discharging control command S5 based on the whole charging / discharging control command S1. The aggregate charge / discharge control command S5 is a target charge / discharge power obtained by disassembling the command value in the overall charge / discharge control command S1 for each power converter 28. When all the power converters 28 are not defective and the same number of storage battery control units 42 are connected, the assembly charge / discharge control command S5 divides the total charge / discharge control command S1 by the number of power converters 28. Value. For example, in the case where eight power converters 28 are provided for the power converter management unit 26, assuming that the entire charge / discharge control command S1 is “charge at 320 kW for 1800 seconds”, the assembly charge / discharge The control command S5 has the content that “the first power converter 28 is charged at 40 kW, the second power converter 28 is charged at 40 kW... The eighth power converter 28 is charged at 40 kW”.

  On the other hand, when the number of storage battery control units 42 actually connected to each power converter 28 is different, the aggregate charge / discharge control in which the charge / discharge power allocated to each power converter 28 is changed according to the number. Command S5 is generated. For example, 20 storage battery control units 42 are actually connected to the first to seventh power converters 28, and 15 storage battery control units 42 are actually connected to the eighth power converter 28. If the total charge / discharge control command S1 is “charge at 320 kW for 1800 seconds”, the “first to first” are set in accordance with the ratio of the number of storage battery control units 42 connected to each power converter 28. The seventh power converter 28 is charged at 41.3 kW, and the eighth power converter 28 is charged at 31 kW.

  The master controller 22 updates the aggregate charge / discharge control command S5 each time the number of storage battery control units 42 connected to each power converter 28 is changed in step ST24.

  Further, since the power converter management data S4 includes information indicating a malfunction of the power converter 28, and the unit state data S3 includes information indicating a malfunction of the storage battery unit 40, the master controller 22 The ratio of the number of the other storage battery units 40 excluding the defective storage battery unit 40 among the storage battery units 40 connected to the other power converters 28 excluding the failed power converter 28. In addition, an aggregate charge / discharge control command S5 for controlling each power converter 28 is generated and output to the power converter management unit 26 so that the charge state required by the overall charge / discharge control command S1 is satisfied. .

  The power converter management unit 26 controls power conversion and voltage conversion in each power converter 28 when charging the storage battery assembly 104 from the power source according to the assembly charge / discharge control command S5. Further, when any of the power converters 28 under the control of the power converter management unit 26 is defective, or when a charge stop instruction command or a standby instruction command is output from the master controller 22 Then, the operation of the malfunctioning power converter 28 is stopped or in a standby state, and information indicating the malfunction of the power converter 28 is transmitted to the master controller 22 as power converter management data S4.

  In this way, it is possible to prevent the power converter 28 not connected to the storage battery control unit 42 from being activated even during charging. In addition, each power converter 28 can be controlled so as to have charging power corresponding to the number of storage battery control units 42 actually connected to each activated power converter 28. Thereby, the current flowing through the storage battery control unit 42 connected to the power converter 28 can be distributed substantially evenly.

  Even during charging, the storage battery unit 40 including the storage battery control unit 42 having the lowest output voltage among all the storage battery control units 42 assigned to one power converter 28 is first connected to the power converter 28. Also good.

  In this case, the output voltage value of the storage battery control unit 42 included in each storage battery unit 40 can be included in the unit state data S3 and output to the master controller 22 via the sub-controller 24. In the master controller 22, the storage battery unit 40 including the storage battery control unit 42 having the lowest output voltage among all the storage battery control units 42 assigned to each power converter 28 is specified, and the power source of the storage battery unit 40 is first turned on. turn on. And the storage battery control unit 42 with the lowest output voltage among the storage battery control units 42 is connected to the parallel connection line L1 first. In this case, it is preferable that the master controller 22 is configured to be able to control on / off of the power source of the power converter 28 via the power converter management unit 26. Subsequent processing is performed in the same manner as steps ST20 to ST26.

  Thereby, the storage battery control unit 42 having the lowest output voltage among all the storage battery control units 42 assigned to each power converter 28 can be connected to the parallel connection line L1 first. Therefore, the charging can be started from the storage battery control unit 42 having a small SOC, and the other storage battery control units 42 are sequentially supplied to the parallel connection line L1 in accordance with the increase in the output voltage due to the charging from the power source to the storage battery control unit 42. You can connect.

  Moreover, it is good also as a structure which directly controls from the master controller 22 each switch contained in the switch circuit 30 performed in the sub controller 24 in the said discharge process and charge process. In this case, the switch control signal S10 can be transmitted from the master controller 22 to the sub-controller 24 as shown in FIG. The master controller 22 performs the control of the switch circuit 30 performed by the sub-controller 24 in the above processing instead.

  With such a configuration, the master controller 22 can directly control the open / closed state of each switch included in the switch circuit 30, and directly captures the actual open / closed state of the switch that has performed the open / close control as switch state data, An assembly charge / discharge control command S5 for each power converter 28 can be generated based on the switch state data.

  Although the example which performs either one of the processes at the time of discharging or charging has been described above, it is also possible to charge the storage battery assembly 104 simultaneously while discharging to the load 110. In this case, when the required power of the load 110 is larger than the supply power of the power source, the connection to the parallel connection line L1 of the storage battery control unit 42 is performed simultaneously with performing the steps ST10 to ST16, which are the processes at the time of discharging. It is preferable to charge the battery assembly 104 from the power source. Thereby, while supplying electric power from the storage battery assembly 104 to the load 110, it is possible to delay the decrease in the amount of charge stored in the storage battery assembly 104 by charging the storage battery assembly 104 from the power source. On the other hand, when the required power of the load 110 is smaller than the supply power of the power source, the connection to the parallel connection line L1 of the storage battery control unit 42 is performed at the same time while performing steps ST20 to ST26, which are the processes at the time of charging described above. It is preferable to discharge from the assembly 104 to the load 110. This is because power can be supplied from the storage battery assembly 104 to the load 110 and the amount of charge stored in the storage battery assembly 104 can be increased by charging the storage battery assembly 104 from the power source.

<Standby processing>
As described above, at the start of discharging and at the start of charging, the power converter 28 is activated after confirming that the storage battery control unit 42 has been connected. When the voltage conversion is stopped, the reverse process is performed. The standby process is performed according to the flowchart of FIG.

  In step ST30, the process which makes the power converter 28 a standby state is performed. When it is determined that the charging process or the discharging process for the storage battery assembly 104 is to be stopped based on the overall charge / discharge control command S1 from the system controller 20, the master controller 22 issues a standby instruction command for instructing the standby of each power converter 28. The assembly charge / discharge control command S5 including the power is output to the power converter management unit 26.

  For example, when the overall charge / discharge control command S <b> 1 indicates that charging / discharging such as “put charging / discharging in a standby state” is unnecessary, the master controller 22 instructs the power converter 28 to wait. Is output to the power converter management unit 26.

  When receiving the assembly charge / discharge control command S5 including the standby instruction command, the power converter management unit 26 sets the power converter 28 under control to the standby state and stops power conversion and voltage conversion.

  In step ST32, it is determined whether or not the power converter 28 is in a standby state, and processing for separating each storage battery unit 40 from the power converter 28 is performed according to the result.

  The sub-controller 24 included in each storage battery unit 40 reads the current value detected by the storage battery current sensor 52 provided in each storage battery unit 40, and transmits unit state data S3 including the detected current value to the master controller 22. To do.

  The master controller 22 receives the unit state data S3 and switches the storage battery unit 40 to the storage battery unit 40 on condition that the sum of the current values of the storage battery control unit 42 becomes the standby current value after setting the power converter 28 to the standby state. A switch control signal S10 for opening is output. The sum of the current values is used as a condition, even if the charging current from the power source to the storage battery unit 40 and the discharge current from the storage battery unit 40 to the load 110 are zero, the storage battery control units 42 (42 This is because the charge / discharge current flows between the resistors (1) to 42 (4)) via the resistor R (R (1) to R (4)). The standby current value is a current value that flows between the power converter 28 and the storage battery unit 40 when the power converter 28 is in a standby state, and is ideally zero.

  In this case, as shown in FIG. 11, it is preferable that the master controller 22 can control the opening / closing of the switches included in the switch circuit 30 with respect to the sub-controller 24 of each storage battery control unit 42. When the sub-controller 24 receives the switch control signal S10 that opens the switch, the sub-controller 24 opens the selection switch SW1, the switch SW2, and the unit switches SW3 and SW4 included in the switch circuit 30 so that the storage battery control units 42 are connected in parallel. Disconnect from L1.

  As described above, in the case where the power converter 28 is set to the standby state, the current flowing between the power converter 28 and each storage battery unit 40 is actually generated after the instruction to set the power converter 28 to the standby state is given. After confirming that the standby current value has been reached, the switches included in the storage battery unit 40 are opened. As a result, the switch included in the switch circuit 30 of the storage battery unit 40 in which the power converter 28 is maintained in a state in which the current flows without being put into a standby state for some reason is forcibly cut off, and a transient current is caused in the switch circuit 30. It is possible to prevent such a large current from flowing. Therefore, deterioration and failure of the switch circuit 30 can be suppressed.

  DESCRIPTION OF SYMBOLS 10 Load power management apparatus, 12 Storage battery power management apparatus, 14 Total power monitoring apparatus, 20 System controller, 22 Master controller, 24 Sub controller, 26 Power converter management part, 28 Power converter, 30 Switch circuit, 40 Storage battery unit, 42 storage battery control unit, 44 storage battery pack, 46 storage battery cell, 52 storage battery current sensor, 54 storage battery voltage sensor, 56 temperature sensor, 60 parallel connection line voltage sensor, 100 power supply system, 102 power supply management system, 104 storage battery aggregate, 106 solar Battery system, 108 system power supply, 110 load, 110a Power management device.

Claims (4)

A storage battery unit including a plurality of storage battery control units each including at least one storage battery cell and connected to a parallel connection line via a selection switch;
A power converter including a cross-flow conversion circuit or a voltage conversion circuit between a power source or a load and the storage battery unit;
A master controller for controlling the power converter;
With
The master controller sets all of the selection switches to an open state after putting the power converter in a standby state. The power supply system according to claim 1,
The power supply system, wherein the master controller outputs a switch control signal for controlling opening and closing of the selection switch. The power supply system according to claim 1 or 2,
A power supply system comprising a sub-controller that directly controls opening and closing of the selection switch for each storage battery unit. The power supply system according to any one of claims 1 to 3,
A system controller that obtains load-side information data indicating a required power status of a load, and generates an overall charge / discharge control command indicating a required charge / discharge power of the entire system based on the load-side information data,
The master controller receives the overall charge / discharge control command from the system controller and calculates a target charge / discharge power of the power converter based on the overall charge / discharge control command.

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