JP2018081929A - Power control device, control method for the same, and control program for the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To resolve a problem that, in a case where a fuel cell stop factor, such as abnormal rise in temperature of a power control device occur, and when such situation that no power for fuel cell shutdown is supplied occurs, a cooling process is hindered, and fatal obstacles may occur to a fuel cell stack.SOLUTION: There is provided a power control device 100 that can connect a plurality of distributed power sources including a fuel cell 1b and an accumulator battery 1c with a system 7. The power control device 100 comprises: a plurality of power supply parts 3a-3c which is individually connected with the plurality of distributed power sources and can supply power; and a control part 103 continuing supply of the power from at least one of the distributed power sources excluding the fuel cell 1b and the system 7 to the fuel cell 1b until shutdown completion, during shutdown of the fuel cell 1b.SELECTED DRAWING: Figure 3

Description

  The present invention relates to a power control apparatus connectable to a fuel cell, a control method for the power control apparatus, and a control program for controlling the power control apparatus.

  In recent years, from the viewpoints of improving energy security that does not depend on petroleum, and clean energy that does not contain nitrogen oxides in the exhaust gas, expectations for power generation systems using fuel cells that generate electricity through the electrochemical reaction of gas have increased. Yes. For example, as in Patent Document 1, a number of fuel cell power supply systems using fuel cells have been proposed.

  This fuel cell can be classified according to the type of electrolyte used. The low temperature type with a reaction temperature of 300 degrees C or less includes the polymer electrolyte (PEFC) and phosphoric acid (PAFC) types. Are in molten carbonate form (MCFC), solid oxide form (SOFC) and the like. Among these, the solid oxide form is characterized in that exhaust heat is easy to use because of high operating temperature, and high power generation efficiency is obtained.

JP-A-7-123609

  For example, in a solid oxide fuel cell, an operating temperature of about 700 to 1000 degrees is required, and a fuel cell stack in which a plurality of cells (battery parts) included in a solid oxide fuel cell are stacked has a high level of ceramics or the like. Heat resistant materials are used. For this reason, if the power generation cell is not cooled sufficiently after the power generation of the fuel cell is stopped, thermal stress is applied due to a rapid temperature change or a temperature difference between the central portion and the peripheral portion. There is a risk that the power generation cell will crack. For this reason, in a fuel cell such as a solid oxide fuel cell, it is recommended that power be supplied from the outside even after power generation is stopped, and that cooling be sufficiently performed.

  An object of the present invention made in view of this point is to provide a power control device, a control method for the power control device, and a control program for the power control device that can extend the life of the fuel cell.

  In order to solve the above-described problems, a power control device according to the present invention is a power control device capable of connecting a plurality of distributed power sources including a fuel cell and a storage battery and a system, and the plurality of distributed power sources A plurality of power supply units that are connected to each other and can supply power, and during the shutdown of the fuel cell, the distributed power source excluding the fuel cell, or at least one of the systems from the system to the fuel cell And a control unit that continues power supply until the shutdown is completed.

  Further, it is preferable that the control unit determines that there is a factor to stop the fuel cell and performs a charging process for charging the storage battery when the operation mode of the fuel cell is generating power.

  Moreover, it is preferable that the said control part determines the kind of factor which should stop the said fuel cell, and makes the said storage battery charge so that the charge amount corresponding to the said kind of factor may be exceeded when performing the said charge process.

  The factor is preferably temperature abnormality detection of the power control device.

  In addition, when the factor occurs, the control unit stops at least one of the power supply unit that does not supply power to the fuel cell or the load connected to the power control device. It is preferable to carry out the treatment.

  Further, it is preferable that the control unit cancels at least a part of the stop processing after the shutdown of the fuel cell is completed and the temperature abnormality detection is resolved.

  In the charging process, it is preferable that the control unit causes the storage battery to charge the amount of power necessary for completing the shutdown of the fuel cell from the distributed power source or the system excluding the storage battery.

  Further, the factor is a stop operation of the fuel cell performed by a user or the like, and the control unit sets a first charge amount preset in the storage battery from the distributed power source or the system excluding the storage battery. It is preferable to perform the charging process for charging the battery.

  Further, the factor is a stop of the fuel cell that is automatically performed periodically, and the control unit is configured such that the factor is determined by a user or the like from the distributed power source or the system other than the storage battery to the storage battery. It is preferable to perform the charging process of charging a second charge amount larger than the first charge amount in the case of the fuel cell stop operation performed.

  Moreover, it is preferable that the said control part determines whether the said fuel cell is generating electric power by the direction of the electric current which flows through the electric power supply part which supplies the electric power to the said fuel cell.

  The fuel cell is preferably a solid oxide fuel cell.

  In order to solve the above-described problems, a control method for a power control apparatus according to the present invention is a control method for a power control apparatus capable of connecting a plurality of distributed power sources including a fuel cell and a storage battery and a system. Then, the processing procedure by the power control device includes the fuel cell operation determining step for determining the operation mode of the fuel cell, and the fuel cell operation determining step when the fuel cell is determined to be shut down in the fuel cell operation determining step. A shutdown power supply step of continuing power supply to the fuel cell from at least one of the distributed power source except the battery or the system until the shutdown is completed.

  Further, in order to solve the above-described problems, a control program for a power control apparatus according to the present invention provides a power control apparatus capable of connecting a plurality of distributed power sources including a fuel cell and a storage battery and a system to the fuel cell. A fuel cell operation determination step for determining the operation mode of the fuel cell, and at least one of the distributed power source excluding the fuel cell or the system when it is determined in the fuel cell operation determination step that the fuel cell is shut down. And a shutdown power supply step of continuing power supply to the fuel cell until the shutdown is completed.

  According to the present invention, even if a fuel cell stop factor such as an abnormal temperature rise occurs in the power control device, power is continuously supplied to the fuel cell, so that the fuel cell can be safely operated without damaging the fuel cell stack. Can be stopped.

The structure of the power control apparatus of one Embodiment of this invention is shown. The operation state at the time of steady operation of the power control device of one embodiment of the present invention is shown. In the electric power control apparatus of one Embodiment of this invention, the control flow until a fuel cell changes from an operation state to a stop state is shown. The power control apparatus of one Embodiment of this invention shows the operation state when an abnormal temperature rise is detected. The power control apparatus of one Embodiment of this invention WHEREIN: The operation state in case the fuel cell connected is being shut down is shown. The relationship between the operation mode of the fuel cell connected to the electric power control apparatus of one Embodiment of this invention and the electric current flow is shown. The operation state at the time of performing a charging process until the fuel cell connected to the electric power control apparatus of one Embodiment of this invention reaches the 1st charge amount or the 2nd charge amount is shown.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

  FIG. 1 is a block diagram showing a configuration of a power control apparatus 100 according to an embodiment of the present invention. A power control apparatus 100 according to the present embodiment includes a power supply device connection unit 101 for connecting a plurality of power supply devices, a load connection unit 102 for connecting to a load, and a control unit 103 for controlling each component. With.

  First, the configuration and operation of the power supply device connection unit 101 will be described. The power supply device connecting unit 101 is a power supply device connection terminal 2a to 2c for connecting the power supply devices 1a to 1c and a voltage for converting DC power input from the power supply device connection terminals 2a to 2c into a desired voltage. Converters 3a to 3c are provided. The power boosted or stepped down by the voltage converters 3 a to 3 c is output to the inverter 4. In this specification, the voltage converters 3a to 3c function as a power supply unit for supplying output power from the power supply devices 1a to 1c to the inverter 4 and the like. Moreover, the voltage converters 3b and 3c function as an electric power supply part for supplying the electric power from the inverter 4 or another power supply device to the fuel cell 1b or the storage battery 1c. Furthermore, the inverter 4 shall function as an electric power supply part for supplying electric power with respect to the specific load 8b.

  The power supply device connection terminals 2a to 2c are power terminals for inputting / outputting power between the power supply devices 1a to 1c and the power control apparatus 100 of the present invention, and the control unit 103 includes power supply devices 1a to 1c. A control signal terminal for performing the control can be provided. In the present embodiment, a power supply device 1a (solar battery), a power supply device 1b (fuel cell), and a power supply device 1c (storage battery) are connected to the power supply device connection terminals 2a to 2c, respectively.

  The solar cell 1a converts the energy of sunlight into direct current power. For example, a large number of photoelectric conversion cells are connected in series and configured to output a predetermined current when irradiated with sunlight. In the present embodiment, for example, a silicon-based polycrystalline solar cell can be used as the solar cell 1a connected to the power supply device connection terminal 2a, but the present invention is not limited to this, and a silicon-based single crystal Any solar cell or thin film solar cell such as CIGS may be used as long as it is capable of photoelectric conversion.

  The fuel cell 1b generates electricity by an electrochemical reaction of gas. In the present embodiment, for example, a solid oxide (SOFC) fuel cell can be used.

  For example, a lithium ion battery is preferably used as the storage battery 1c used in this embodiment, but other types of storage batteries such as a nickel metal hydride battery can also be used. In addition to a single storage battery, it is also possible to charge a storage battery mounted on an electric vehicle (EV) or a plug-in hybrid vehicle (PHV).

  The voltage converters 3a to 3c perform DC / DC conversion so that the DC output voltages of the power supply devices 1a to 1c become predetermined DC voltage values. More specifically, the voltage converters 3a to 3c have DC / DC conversion circuits, and based on the control signal 10 from the control unit 103, the DC input voltages from the respective power supply devices 1a to 1c are set to predetermined target values. The voltage is boosted to a voltage value and then output to the inverter 4.

  The voltage converters 3 b and 3 c can perform bidirectional DC / DC conversion. For example, the voltage converter 3 c in FIG. 1 boosts or decreases the DC output power from the power supply device 1 c (storage battery) to the inverter 4. In addition, the DC input power from the inverter 4 or other voltage converters 3a and 3b can be stepped down or boosted and supplied to the power supply device 1c (storage battery).

  The power supply devices 1a to 1c connected to the power supply device connection terminals 2a to 2c have different DC input voltages from each other, but in this embodiment, voltage conversion is performed with different adjustment amounts according to the DC input voltages. Thus, the voltage is boosted to the same target voltage value.

  The fuel cell management unit 104 acquires information about the direction in which the current flows in the voltage converter 3b, and appropriately transmits the information to the control unit 103. As will be described later, the control unit 103 determines whether the power supply device 1b (fuel cell) is in a start, power generation, shutdown, or stop state depending on the direction in which the current flows.

  The power supply device 1a connected to the power supply device connection terminal 2a may include a solar battery, a wind power generator, a small hydraulic power generator, or the like that rectifies and outputs AC power.

  Next, the configuration and operation of the load connection unit 102 will be described. The load connection unit 102 includes an inverter 4 that converts power from each of the power supply devices 1a to 1c and a load connection terminal 6b that connects an output of the inverter 4 to a specific load 8b. Furthermore, the load connection unit 102 includes a system connection terminal 6 a for connecting the commercial power supply system 7 to the power control apparatus 100.

  In addition, the load connection unit 102 selects a switch 5a for turning on / off the connection with the commercial power supply system 7 and whether or not to supply power from the commercial power supply system 7 or the inverter 4 to the specific load 8b. Switch 5b and a switch 5c for selecting whether or not to supply the output power of each of the power supply devices 1a to 1c to the inverter 4. Each switch is configured by a relay, a transistor, and the like, and is configured to switch the on / off state based on a control signal 10 from the control unit 103. A general load 8 a other than the specific load 8 b is connected between the commercial power supply system 7 and the system connection terminal 6 a and receives power supply from the commercial power supply system 7.

  Based on the control signal 10 from the control unit 103, the inverter 4 converts the power after voltage conversion from each of the power supply devices 1a to 1c into power corresponding to the specific load 8b to be supplied. In the present embodiment, the inverter 4 converts the power after voltage conversion from each of the power supply devices 1a to 1c into AC 100V. The electric power converted into AC 100V is supplied to the specific load 8b connected to the load connection terminal 6b.

  The system connection terminal 6a and the load connection terminal 6b are controlled so that the control unit 103 can control each load in addition to a power terminal for inputting and outputting power between the commercial power supply system 7 and the specific load 8b. A signal terminal can be provided. In the present embodiment, a commercial power supply system 7 is connected to the system connection terminal 6a, and a general load 8a is connected between the system connection terminal 6a and the commercial power supply system 7 via a distribution board or the like. . When the power control apparatus 100 and the load 8a and the specific load 8b are connected by communication such as the ECHONET Lite (registered trademark) standard, the control unit 103 transmits the control signal 10 so that the load 8a and the specific load 8b are connected. The operation of the specific load 8b can be controlled.

  A specific load 8b that operates at 100 V AC is connected to the load connection terminal 6b. Examples of the specific load 8b that operates at AC 100V include electrical products that should avoid power outages as much as possible, such as refrigerators, emergency lights, hot water supply systems, and home network servers. On the other hand, the load 8a is a general household load driven by AC 100V, and examples thereof include a dryer, a home game machine, or an audio system for listening to music.

  In this embodiment, the path of the control signal 10 for the control unit 103 to control each component is indicated by a broken line in FIG. 1, but the transmission of the control signal 10 may use wired communication. Wireless communication may be used.

  The control unit 103 may be configured by hardware, or a function may be realized by causing a CPU to execute a program.

  Although it has been described that the voltage converters 3a to 3c and the inverter 4 in the present embodiment control the output voltage by the control unit 103, the present invention is not limited to this, and is set up to have a predetermined output voltage. It may be.

  In this embodiment, a single-phase AC 100V is output from the load connection terminal 6b as an AC power output, but a three-phase three-wire 200V is often used for a commercial refrigerator or air conditioner, motor drive in a factory, and the like. In order to be used, instead of the inverter 4, an inverter 4 ′ for converting to the three-phase 200V may be arranged.

  In the present embodiment, the load to be connected is described assuming an electric device that can be used in Japan. However, the load can be appropriately changed in consideration of the use of an electric device that can be used outside of Japan. For example, the inverter 4 can output AC 220 to 240 V and can be configured to be connectable to electrical equipment that can be used in Asia, Oceania, and Europe.

  Next, a state when the power control apparatus 100 according to the embodiment of the present invention is performing a steady operation will be described with reference to FIG. In the steady operation state shown in FIG. 2, the switches 5b and 5c are in an on state, and the voltage converters 3a to 3c and the inverter 4 are also in an on state. Thick line arrows indicate the path and direction of power flow. Both the power supply devices 1a (solar cells) and 1b (fuel cells) perform a power generation operation, and the DC power converted by the voltage converters 3a and 3b is converted into AC power by the inverter 4 and supplied to the specific load 8b. In addition, a part of the DC power converted by the voltage converters 3a and 3b is stepped down or boosted by the voltage converter 3c, and the power supply device 1c (storage battery) is used until the charge amount reaches a preset first power amount. ) Is charged. Electric power is supplied to the general load 8 a from the commercial power supply system 7, but the switch 5 a is in an off state, and the power control device 100 is disconnected from the commercial power supply system 7.

  Next, in the power control apparatus 100 according to the embodiment of the present invention, when one of a plurality of factors for shutting down the fuel cell 1b occurs, an operation for safely shutting down the fuel cell 1b is performed. explain. In the present embodiment, it is assumed that the fuel cell 1b should be shut down. First, when an abnormal temperature rise occurs in at least some of the functional blocks of the power control apparatus 100, secondly, use is made. When a person performs a stop operation by pressing a fuel cell stop button or the like, and thirdly, for example, when the fuel cell 1b is automatically stopped for 24 hours as a gas leak detection measure once a month.

  A case where an abnormal temperature increase occurs in at least a part of the functional blocks of the power control apparatus 100, which is the first stop factor described above, will be described. In the power control apparatus 100, there are a plurality of functional blocks that generate heat during operation, such as the inverter 4, voltage converters 3a to 3c, and a CPU (Central Processing Unit) in the control unit. Moreover, about the inverter 4 and the voltage converters 3a-3c, the emitted-heat amount changes with the operating conditions of the specific load 8b and the power supply devices 1a-1c to be connected. Therefore, when an abnormal temperature rise occurs in at least some of the functional blocks in the power control apparatus 100, the power supply unit that does not supply power to the fuel cell 1b or a specific load connected to the power control apparatus 100 At least one of the low priority among 8b is stopped. In addition, after charging the storage battery 1c with the amount of power necessary for shutting down the fuel cell 1b, the operation proceeds to the shutdown operation of the fuel cell 1b, and the power supply to the fuel cell 1b is continued until the fuel cell 1b completes the shutdown. To do.

  The case where the user performs a stop operation by pressing the fuel cell stop button or the like, which is the second stop factor described above, is when the user manually stops the fuel cell 1b for reasons such as maintenance, for example. It is. Even in such a case, when a power failure occurs during the shutdown of the fuel cell 1b, it is necessary to always supply power from the storage battery 1c to the fuel cell 1b. Moreover, even if a power failure or the like occurs while the fuel cell 1b is stopped, it is desirable that the operation of the specific load 8b having a high priority can be continued by supplying power from the storage battery 1c. Therefore, the storage battery 1c is charged by the first power amount set in advance as the minimum necessary power amount and then shut down.

  Next, a case where the fuel cell 1b is automatically stopped for 24 hours, for example, once a month as a measure for detecting gas leakage, which is the third stop factor described above, will be described. The fuel cell 1b generates electricity by the electrochemical reaction of the supplied gas. However, in particular, when operating in a steady state, a constant amount of gas continues to be consumed for a long time. Judgment may stop the gas supply. In order to avoid such gas supply stoppage due to erroneous gas leakage detection, a certain type of fuel cell is intentionally stopped, for example, once a month for about 24 hours. Even in such a case, when a power failure occurs during the shutdown of the fuel cell 1b, it is necessary to always supply power from the storage battery 1c to the fuel cell 1b. Further, it is desirable that the user can supply power to the specific load 8b by supplying power from the storage battery 1c even if a power failure or the like occurs during 24 hours when the fuel cell 1b is intentionally stopped. Therefore, the power control apparatus 100 causes the storage battery 1c to be charged by a second power amount larger than the first power amount described above, and then shuts down the fuel cell 1b.

  Next, the control flow for safely shutting down the fuel cell 1b in the power control apparatus 100 according to the present embodiment will be described in detail with reference to FIG.

(Control flow when abnormal temperature rises)
The control unit 103 in the power control apparatus 100 determines whether or not there is a factor for stopping the power supply device 1b (fuel cell) in FIG. 3 (S301). The determination in step S301 is performed by the control unit 103 confirming a device stop factor determination flag provided for each power supply device. If there is no stop factor for the fuel cell 1b, the control flow ends. If there is a stop factor, it is further determined whether or not the cause is an abnormal temperature rise (S302). The control unit 103 periodically acquires temperature information from a temperature sensor provided for each functional block in the power control system, and determines whether there is an abnormal temperature rise based on the temperature information. Then, when the stop factor is an abnormal temperature increase, one or a plurality of loads having a low priority among the specific loads 8b are stopped (S303). Further, in the present embodiment, the switch 5c is turned off and the inverter 4 is also turned off, so that power is supplied to the specific load 8b in the on state from the commercial power supply system 7 (S303). The operating state of the power control apparatus 100 at this time is shown in FIG. With these controls, a part of the power supply unit that is a heat generation source in the power control apparatus 100 is turned off, and an abnormal temperature rise can be eliminated.

  In step S303 of the present embodiment, a part of the specific load 8b and the inverter 4 are both stopped. However, even if only the specific load 8b is stopped, the amount of heat generated in the inverter 4 is reduced and the abnormal temperature is decreased. In some cases, the rise can be resolved. Further, when power supply from the power supply device 1a (solar cell) cannot be expected at night, the voltage converter 3a is further turned off in step S303 to further suppress the temperature rise in the power control apparatus 100. Can do. Alternatively, the voltage converters 3a and 3b may be turned off and the inverter 4 may be turned on to charge the storage battery 1c from the commercial power supply system 7. Also, when the stop factor of the fuel cell 1b is an abnormal temperature rise, the load or the like is stopped immediately in step S303. However, the load or the like is stopped after the fuel cell 1b shifts to shutdown. May be.

  Next, the control unit 103 determines whether or not the fuel cell 1b is generating power (S304). If the fuel cell 1b is generating power, the amount of power charged in the storage battery 1c further shuts down the fuel cell 1b. It is determined whether or not the required power amount is exceeded (S305).

An example of the procedure is shown below. The control unit 103 includes an amount of electric power W _S required for shutting down the fuel cell 1b, an amount of electric power W _L consumed during shutdown by the power control apparatus 100 including the load device, and another power source device (solar cell 1a, to calculate the supply electric energy that can be W _P from the storage battery 1c). Then, it is determined whether or not the calculated W _S , W _L, and W _P satisfy the relationship of Expression (1) (S305).

W _P - W _L> W _S-type (1)

Wherein formula (1), from the amount of power W _P can be supplied from another power device, it is subtracted power consumption W _L of the power control device 100 including the load, Note power required to shut down the fuel cell 1b which means that it is possible to cover the amount W _S. W _L in the formula (1) is intended to include the power consumption of the power supply unit such as the specific loading 8b and the inverter 4, it shall apply a value corresponding to the ON / OFF state of each power device and the loads.

  The control part 103 determines whether Formula (1) is satisfy | filled, If it determines with not satisfy | filling Formula (1), it will charge further with respect to the storage battery 1c, and will continue until Formula (1) is satisfy | filled.

  If it determines with the charge amount of the storage battery 1c satisfy | filling Formula (1), the control part 103 will start the shutdown operation | movement of the fuel cell 1b next (S306). In the shutdown operation of the fuel cell 1b, as described above, power is supplied from the outside so that the power generation cell is not cracked, and cooling is performed with sufficient time. FIG. 5 shows the operating state of the power control apparatus 100 after the start of the shutdown of the fuel cell 1b. In FIG. 5, the power at the time of shutdown of the fuel cell 1 b is described as being supplied from the solar cell 1 a and the storage battery 1 c, but may be configured to be supplied from only one of them, You may comprise so that it may be supplied from the power supply system 7. FIG.

  Next, the control unit 103 determines whether or not the shutdown operation is completed (S307). For this determination, for example, information such as the direction of the current flowing through the voltage converter 3b that supplies the shutdown power to the fuel cell 1b can be used as will be described later.

  When it is determined that the shutdown of the fuel cell 1b has been completed, the control unit 103 further determines whether or not the abnormal temperature rise has been resolved (S311). When the abnormal temperature rise is eliminated, the partial stop of the specific load 8b executed in step S303 is canceled (S312). This is because the shutdown operation of the fuel cell 1b that should avoid power supply stop has been completed, so that all the specific loads 8b that should be continuously operated are returned to the operating state. If step S303 is not executed, step S312 is not executed.

  If the control unit 103 determines in step S311 that the abnormal temperature rise has been resolved with sufficient margin, the control unit 103 simultaneously cancels all the stops including the stop of the inverter 4 in step S303 in step S312.

  If the control unit 103 determines in step S304 that the operation mode of the fuel cell 1b is not generating power, the control unit 103 next determines whether or not the fuel cell 1b is being shut down (S308). When the control unit 103 determines that the fuel cell 1b is being shut down, the control unit 103 then proceeds to determination of whether or not the shutdown has been completed (S307). The subsequent control flow is the same as when the fuel cell 1b is generating power.

  When the control unit 103 determines in step S308 that the operation mode of the fuel cell 1b is not shutting down, the control unit 103 next determines whether or not the fuel cell 1b is being activated (S309). When determining that the fuel cell 1b is being activated, the control unit 103 performs a process for stopping the fuel cell 1b (S310). Then, after stopping the fuel cell 1b, the control unit 103 determines whether or not the abnormal temperature rise of the power control apparatus 100 has been eliminated (S311). The control flow thereafter is the same as when the operation mode of the fuel cell 1b is generating power.

  By the way, in steps S304, S308, S309, and S307 of the above-described control flow, the control unit 103 determines the operation mode of the fuel cell 1b. The determination method will be described. This determination is performed by the fuel cell management unit 104 in FIG. 1 monitoring the direction of current flow in the voltage converter 3 b with a current sensor and appropriately transmitting the result to the control unit 103. FIG. 6 shows the current flowing through the voltage converter 3b when the horizontal axis is the time axis and the vertical axis is the direction in which the current flows from the fuel cell 1b to the inverter 4. In FIG. 6, when the fuel cell 1b is stopped (T1), the current flowing through the voltage converter 3b is zero. However, when the fuel cell 1b enters the start state (T2), the fuel cell 1b is supplied with electric power from the outside (that is, FIG. 6) Increase the cell temperature. When the cell temperature reaches a predetermined temperature and becomes capable of generating power, the fuel cell 1b starts generating power (T3). Next, the fuel cell 1b shifts to the shutdown mode for the above-described reason when the power generation is stopped due to maintenance / inspection, for example (T4). Here, in order to gradually cool the cell temperature as described above, the shutdown is completed over a certain period of time by receiving power supply from the outside. When the shutdown is completed, the current flowing through the voltage converter 3b becomes zero (T5).

  The control unit 103 acquires information on the direction of the current flowing through the voltage converter 3b via the fuel cell management unit 104. The control unit 103 determines that power generation is being performed as long as the positive current is continuously detected from the time when the current is switched from negative to positive by using the current characteristic of FIG. Further, it is determined that the shutdown is in progress as long as the negative current is continuously detected from the time when the current is switched from positive to negative. Further, it is determined that the fuel cell 1b has stopped when the current continues to be zero after detecting the shutdown. Then, it is determined that the fuel cell 1b is being activated as long as the current changes from a zero state to a negative current and the negative current is continuously detected.

(Control flow for manual stop by the user)
If the control unit 103 in the power control apparatus 100 determines in FIG. 3 that there is a factor that should stop the fuel cell 1b, but that is not an abnormal temperature rise, whether or not the factor is a manual stop by the user. Is determined (S313). The manual stop by the user means a stop operation that is executed when the user performs an operation such as pressing a stop button for the purpose of maintenance of the fuel cell 1b. When it is determined that the factor that should stop the fuel cell 1b is a manual stop by the user, the control unit 103 next determines whether or not the fuel cell 1b is generating power (S314). Also in this determination, the control unit 103 determines whether or not power generation is being performed using the current characteristics of FIG. 6 as in step S304.

  When determining that the fuel cell 1b is generating power in step S314, the control unit 103 determines whether or not the charge amount of the storage battery 1c is equal to or greater than a predetermined first charge amount (S315). The first charge amount here is, for example, when the power control apparatus 100 is shut down, calculated from the power consumption of the specific load 8b that the user always wants to use in an emergency such as a power outage and the average power outage time. It is the sum of the electric energy that should be ensured in the storage battery 1c at the minimum and the electric energy necessary for the shutdown operation of the fuel cell 1b. On the other hand, if it is determined in step S314 that the fuel cell 1b is not generating power, the control unit 103 determines whether or not the fuel cell 1b is being shut down (S308). The subsequent control flow is the same as when the fuel cell 1b should be stopped due to an abnormal temperature rise.

  If the control part 103 determines with the electric energy in the storage battery 1c not being more than 1st charge amount in step S315, it will charge the storage battery 1c. In FIG. 7, the operation state at the time of a charge process in case the electric energy which can be utilized in the storage battery 1c is not more than 1st charge amount is shown. Electric power is supplied from the commercial power supply system 7 to the general load 8a and the specific load 8b, and electric power generated in the fuel cell 1b is supplied to the storage battery 1c. This charging process is continued until the amount of power in the storage battery 1c becomes equal to or greater than the first amount of charge. On the other hand, if the control part 103 determines with the electric energy in the storage battery 1c being more than 1st charge amount in step S315, the shutdown of the fuel cell 1b will be started (S306). The subsequent control flow is the same as when the fuel cell 1b should be stopped due to an abnormal temperature rise.

  In the present embodiment, the first charge amount is a sufficient amount of power with respect to the amount of power required for shutting down the fuel cell 1b, and the amount of power that can be discharged by the storage battery 1c is equal to or greater than the first charge amount. If this amount of power is secured, the fuel cell 1b can be safely shut down.

  In step S315, the electric power generated by the fuel cell 1b is operated so as to charge the storage battery 1c. However, the electric power from the solar cell 1a or the commercial power supply system 7 may be used for charging.

(Control flow for periodic automatic stop)
When the control unit 103 in the power control apparatus 100 determines in step S313 in FIG. 3 that there is a factor that should stop the fuel cell 1b but that it is not a manual stop by the user, the stop factor is periodically It is determined that the automatic stop has occurred, and it is determined whether or not the fuel cell 1b is generating power (S316). Also in this determination, the control unit 103 determines whether or not power generation is being performed using the current characteristics of FIG. 6 as in step S304.

  When determining that the fuel cell 1b is generating power in step S316, the control unit 103 determines whether or not the charge amount of the storage battery 1c is equal to or greater than a predetermined second charge amount (S317). The second charge amount here is calculated from the power consumption of the specific load 8b that the user always wants to use even when the fuel cell 1b is periodically stopped for 24 hours as a measure against gas leakage, for example. This is the sum of the amount of power to be secured in the storage battery 1c after the shutdown of the fuel cell 1b and the amount of power necessary for the shutdown operation of the fuel cell 1b. On the other hand, if it is determined in step S316 that the fuel cell 1b is not generating power, the control unit 103 next determines whether or not the fuel cell 1b is being shut down (S308). The subsequent control flow is the same as when the fuel cell 1b should be stopped due to an abnormal temperature rise.

  If the control part 103 determines in step S317 that the electric energy in the storage battery 1c is not more than 2nd charge amount, it will charge the storage battery 1c. The charging process in this case is performed in the same manner as when the user manually stops the fuel cell 1b. For example, the general load 8a and the specific load 8b are supplied with power from the commercial power supply system 7 as shown in FIG. This is performed by supplying power from the fuel cell 1b to the storage battery 1c. This charging is continued until the amount of power in the storage battery 1c becomes equal to or greater than the second amount of charge. On the other hand, if the control part 103 determines with the electric energy in the storage battery 1c being more than 2nd charge amount in step S317, it will start the shutdown of the fuel cell 1b (S306). The subsequent control flow is the same as when the fuel cell 1b should be stopped due to an abnormal temperature rise.

  In the present embodiment, since the second charge amount is larger than the first charge amount, the amount of power is sufficiently large with respect to the amount of power necessary for shutting down the fuel cell 1b, and the storage battery 1c can be discharged. If the amount of electric power equal to or greater than the second amount of charge is secured as a sufficient amount of electric power, the fuel cell 1b can be safely shut down.

  As described above, according to one embodiment of the present invention, even if a factor for stopping the fuel cell occurs, power is continuously supplied to the fuel cell that is shut down preferentially from at least the storage battery. The fuel cell can be safely stopped without damaging the fuel cell stack.

  According to an embodiment of the present invention, even if an abnormal temperature rise of the power control device occurs, power is preferentially given from at least the storage battery to the fuel cell that is shutting down while suppressing the temperature rise in the device. Therefore, the fuel cell can be safely stopped without damaging the fuel cell stack.

  In addition, according to an embodiment of the present invention, even if a manual stop operation of the fuel cell by the user occurs, power is continuously supplied at least preferentially from the storage battery to the fuel cell being shut down. The fuel cell can be safely stopped without damaging the cell stack. Further, even if a failure such as a power failure occurs after the fuel cell is stopped, power can be supplied to a specific load that the user always wants to use.

  In addition, according to an embodiment of the present invention, even when a periodic fuel cell automatic stop as a gas leakage detection measure occurs, power is preferentially supplied from the storage battery to the fuel cell that is shut down. Therefore, the fuel cell can be safely stopped without damaging the fuel cell stack. Further, even if a failure such as a power failure occurs after the fuel cell is stopped, it is possible to supply power to a specific load that the user always wants to use during the stop period.

  In the present embodiment, the control flow is configured assuming three factors as factors for stopping the fuel cell 1b, but the present invention is not limited to this configuration. Step S302 of FIG. 3 may be configured including occurrence of an abnormality other than an abnormal temperature rise, or a step different from step S302 may be executed for each type of abnormality.

  Although the present invention has been described based on the drawings and examples, it should be noted that those skilled in the art can easily make various changes or modifications based on the present disclosure. Therefore, it should be noted that these variations or modifications are included in the scope of the present invention. For example, the functions included in each member, each means, each step, etc. can be rearranged so as not to be logically contradictory, and a plurality of means, steps, etc. can be combined into one or divided. Is possible.

1a Power supply device (solar cell)
1b Power supply equipment (fuel cell)
1c Power supply equipment (storage battery)
2a-2c Power supply device connection terminal 3a-3c Voltage converter 4 Inverter 5a-5c Switch 6a System connection terminal 6b Load connection terminal 7 Commercial power supply system 8a Load 8b Specific load 10 Control signal 100 Power control device 101 Power supply device connection unit 102 Load Connection unit 103 Control unit 104 Fuel cell management unit

  In order to solve the above-described problems, a power control device according to the present invention is a power control device that can be connected to at least one distributed power source including a first distributed power source, and causes the first distributed power source to stop. According to this, a control unit that executes different control is provided.

  Moreover, it is preferable that the said control part determines the kind of factor of the said stop.

  Moreover, it is preferable that the said control part performs different control according to the kind of apparatus which the said factor of a stop generate | occur | produces.

  Moreover, it is preferable that the type of the device includes at least one of the power control device and the first distributed power source.

  In addition, the control unit may execute different controls according to the cause of the stop including at least one of temperature abnormality, manual stop performed by a user, and automatic stop periodically performed automatically. preferable.

  Moreover, it is preferable that the said control part performs different control according to the factor of the said stop, and the operation mode of a said 1st distributed power supply.

  The operation mode of the first distributed power source preferably includes at least one of start-up, power generation, shutdown, and stop.

  Moreover, it is preferable that the said control part performs the stop process which stops the load connected to the said power control apparatus, when the factor of the said stop is the temperature abnormality of the said power control apparatus.

  The at least one distributed power supply may further include a second distributed power supply capable of supplying power to the first distributed power supply.

  Further, the control unit stops the power supply when the cause of the stop is a temperature abnormality of the power control apparatus and the second distributed power supply is not supplying power to the first distributed power supply. It is preferable to perform stop processing.

In addition, during the shutdown of the first distributed power supply, the control unit supplies power to the first distributed power supply from at least one of the second distributed power supply and a system until the first distributed power supply is shut down. It is preferable to continue the supply.
In addition, when the second distributed power source is a storage battery, the control unit determines that there is a cause of the stop, and when the operation mode of the first distributed power source is generating power, the factor of the stop It is preferable to perform a charging process for charging the storage battery so as to exceed a charge amount of electric power capable of executing control corresponding to.
In addition, when the cause of the stop is a manual stop, the control unit performs a charging process of charging a first charge amount preset in the storage battery from the at least one distributed power source or system other than the storage battery. Preferably it is done.
In addition, when the cause of the stop is an automatic stop, the control unit has a second charge amount larger than a first charge amount set in advance in the storage battery from the at least one distributed power source or system excluding the storage battery. It is preferable to perform the charging process for charging the amount of charge.
Moreover, it is preferable that the said control part determines whether the said 1st distributed power supply is generating electric power by the direction of the electric current which flows with the electric power supply to the said 1st distributed power supply.
Moreover, it is preferable that the said control part cancels at least one part of the said stop process, after the shutdown of a said 1st distributed power supply is completed and temperature abnormality is eliminated.
The first distributed power source is preferably a fuel cell.

  In order to solve the above-described problems, a control method for a power control apparatus according to the present invention is a control method for a power control apparatus that can be connected to at least one distributed power supply including a first distributed power supply. A step of determining whether or not there is a cause of stoppage of one distributed power supply; a step of determining the type of the cause of the stop when there is a cause of the stop; and a step of executing different control depending on the cause of the stop It is characterized by including.

In order to solve the above-described problems, a control program for a power control apparatus according to the present invention provides a power control apparatus that can be connected to at least one distributed power supply including the first distributed power supply to stop the first distributed power supply. Determining whether there is a cause of the stop, determining the type of the cause of the stop when there is the cause of the stop, and executing different control depending on the cause of the stop It is characterized by.

Claims (13)

A power control device capable of connecting a plurality of distributed power sources including a fuel cell and a storage battery and a system,
A plurality of power supply units to which the plurality of distributed power sources are respectively connected and capable of supplying power;
A control unit that continues power supply to the fuel cell from at least one of the distributed power source excluding the fuel cell or the system until the shutdown is completed during the shutdown of the fuel cell. Power control device. The controller is
The power control apparatus according to claim 1, wherein it is determined that there is a factor to stop the fuel cell, and a charging process for charging the storage battery is performed when an operation mode of the fuel cell is generating power. The controller is
The power control device according to claim 2, wherein a type of a factor to stop the fuel cell is determined, and the storage battery is charged so as to exceed a charge amount corresponding to the type of the factor when performing the charging process.   The power control apparatus according to claim 2, wherein the factor is temperature abnormality detection of the power control apparatus.   The control unit performs stop processing for stopping at least one of the power supply unit that does not supply power to the fuel cell or the load connected to the power control device when the factor occurs. The power control device according to claim 4, which is performed.   The power control device according to claim 5, wherein the control unit cancels at least a part of the stop processing after the shutdown of the fuel cell is completed and the temperature abnormality detection is resolved.   The said charging part WHEREIN: The said control part makes the said storage battery charge the electric energy required for the shutdown completion of the said fuel cell from the said distributed power supply except the said storage battery, or the said system | system | group. The power control device described in 1. The factor is a stop operation of the fuel cell performed by a user or the like,
4. The power control device according to claim 2, wherein the control unit performs the charging process of charging the storage battery with a first charge amount set in advance from the distributed power source or the system excluding the storage battery. 5. The factor is a stoppage of the fuel cell that is automatically performed periodically.
The control unit has a higher charge amount than the first charge amount when the factor is a stop operation of the fuel cell performed by a user or the like from the distributed power source or the system excluding the storage battery to the storage battery. The power control apparatus according to claim 2, wherein the charging process for charging a charge amount of 2 is performed.   The said control part determines whether the said fuel cell is generating electric power according to the direction of the electric current which flows through the electric power supply part which supplies the electric power to the said fuel cell. Power control device.   The power control apparatus according to any one of claims 1 to 10, wherein the fuel cell is a solid oxide fuel cell. A control method of a power control device capable of connecting a plurality of distributed power sources including a fuel cell and a storage battery, and a system, wherein the processing procedure by the power control device includes:
A fuel cell operation determination step for determining an operation mode of the fuel cell;
When it is determined in the fuel cell operation determination step that the fuel cell is being shut down, the shutdown is completed for the fuel cell from at least one of the distributed power source excluding the fuel cell or the system. And a shutdown power supply step of continuing the power supply until the power control apparatus is controlled. To a power control device that can connect a plurality of distributed power sources including a fuel cell and a storage battery and a system,
A fuel cell operation determination step for determining an operation mode of the fuel cell;
When it is determined in the fuel cell operation determination step that the fuel cell is being shut down, the shutdown is completed for the fuel cell from at least one of the distributed power source excluding the fuel cell or the system. A control program for a power control apparatus, comprising: a shutdown power supply step for continuing power supply until

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