WO2012124298A1 - 燃料電池システム及びその運転方法 - Google Patents
燃料電池システム及びその運転方法 Download PDFInfo
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- WO2012124298A1 WO2012124298A1 PCT/JP2012/001601 JP2012001601W WO2012124298A1 WO 2012124298 A1 WO2012124298 A1 WO 2012124298A1 JP 2012001601 W JP2012001601 W JP 2012001601W WO 2012124298 A1 WO2012124298 A1 WO 2012124298A1
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- water
- fuel cell
- cell system
- power
- temperature
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01M—PROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
- H01M8/00—Fuel cells; Manufacture thereof
- H01M8/04—Auxiliary arrangements, e.g. for control of pressure or for circulation of fluids
- H01M8/04298—Processes for controlling fuel cells or fuel cell systems
- H01M8/04694—Processes for controlling fuel cells or fuel cell systems characterised by variables to be controlled
- H01M8/04701—Temperature
- H01M8/04723—Temperature of the coolant
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01M—PROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
- H01M8/00—Fuel cells; Manufacture thereof
- H01M8/04—Auxiliary arrangements, e.g. for control of pressure or for circulation of fluids
- H01M8/04007—Auxiliary arrangements, e.g. for control of pressure or for circulation of fluids related to heat exchange
- H01M8/04029—Heat exchange using liquids
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01M—PROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
- H01M8/00—Fuel cells; Manufacture thereof
- H01M8/04—Auxiliary arrangements, e.g. for control of pressure or for circulation of fluids
- H01M8/04298—Processes for controlling fuel cells or fuel cell systems
- H01M8/04313—Processes for controlling fuel cells or fuel cell systems characterised by the detection or assessment of variables; characterised by the detection or assessment of failure or abnormal function
- H01M8/0432—Temperature; Ambient temperature
- H01M8/04358—Temperature; Ambient temperature of the coolant
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01M—PROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
- H01M8/00—Fuel cells; Manufacture thereof
- H01M8/04—Auxiliary arrangements, e.g. for control of pressure or for circulation of fluids
- H01M8/04298—Processes for controlling fuel cells or fuel cell systems
- H01M8/04313—Processes for controlling fuel cells or fuel cell systems characterised by the detection or assessment of variables; characterised by the detection or assessment of failure or abnormal function
- H01M8/04537—Electric variables
- H01M8/04604—Power, energy, capacity or load
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01M—PROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
- H01M8/00—Fuel cells; Manufacture thereof
- H01M8/04—Auxiliary arrangements, e.g. for control of pressure or for circulation of fluids
- H01M8/04298—Processes for controlling fuel cells or fuel cell systems
- H01M8/04694—Processes for controlling fuel cells or fuel cell systems characterised by variables to be controlled
- H01M8/04701—Temperature
- H01M8/04731—Temperature of other components of a fuel cell or fuel cell stacks
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02E—REDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
- Y02E60/00—Enabling technologies; Technologies with a potential or indirect contribution to GHG emissions mitigation
- Y02E60/30—Hydrogen technology
- Y02E60/50—Fuel cells
Definitions
- the present invention relates to a fuel cell system including a fuel cell that generates power using hydrogen-rich fuel gas and oxidant gas, and an operation method thereof.
- the fuel cell system is a system that generates electric power and heat through an electrochemical reaction between a fuel gas (hydrogen-containing gas) and an oxidant gas (for example, air) supplied to the fuel cell.
- a fuel gas hydrogen-containing gas
- an oxidant gas for example, air
- the generated electric power is supplied to some electric power loads (for example, electrical appliances such as lighting and air conditioners) used at home.
- heat generated by power generation is recovered by cooling water supplied to the inside of the fuel cell.
- the recovered heat is recovered as hot water through a heat exchanger, for example, and supplied to a heat load in the home (for example, a heat utilization device such as a hot water supply device or floor heating).
- the fuel cell system is usually provided with a reformer for generating a hydrogen-containing gas.
- a hydrogen-containing gas is generated by subjecting a raw material gas (for example, city gas (natural gas) or the like) and water to a steam reforming reaction in a reforming catalyst.
- Such a fuel cell system often employs a method of using water collected inside the system as a water supply source of water or cooling water supplied to the reformer, that is, supplying water independently.
- Examples of a method for recovering water inside the fuel cell system include a method for condensing and recovering water by cooling water vapor contained in the fuel gas and oxidant gas discharged from the fuel cell.
- the water recovered in the fuel cell system does not contain a sterilizing component such as a chlorine component and is in a state suitable for the growth of microorganisms such as fungi and bacteria.
- a sterilizing component such as a chlorine component
- the flow path through which the recovered water flows may cause a blockage or a narrowing of the flow path, which may impair the water supply function or the purification function.
- the temperature of the cooling water is detected, and when it is determined that the temperature of the cooling water has become equal to or lower than a predetermined temperature and that a predetermined time has passed thereafter, the temperature of the cooling water is set.
- a fuel cell power generator that raises the temperature to a predetermined temperature or higher is known (see, for example, Patent Document 1).
- the temperature of the water supplied to the water purification device is the predetermined temperature for the second predetermined period.
- a fuel cell power generation system that controls the temperature adjusting means so as to be equal to or lower than the deterioration temperature of the ion exchange resin (see, for example, Patent Document 2).
- the temperature detector does not operate. Is not performed, and there is a risk that bacteria will multiply before the power failure is resolved. Further, even after the power failure is resolved, if the predetermined time has not elapsed, the temperature raising process is not performed, so that bacteria may grow during that time. Furthermore, even when the fuel cell power generation system is stopped for a long time with water remaining in the fuel cell power generation system, power is not supplied to the fuel cell power generation system, so that bacteria may grow.
- the conventional fuel cell power generation system still has room for improvement in terms of suppressing the growth of microorganisms such as bacteria.
- the present invention solves the above-described conventional problems.
- the microorganisms are heat sterilized to thereby reduce the conventional fuel.
- An object of the present invention is to provide a fuel cell system that can suppress the growth of microorganisms more than the battery system.
- a fuel cell system is a fuel cell system including a fuel cell, and includes a cooling water path through which cooling water for cooling the fuel cell flows, and the cooling water path.
- a cooling water tank for storing the cooling water provided a recovery water tank for storing water generated in the fuel cell system, a water circulation path through which water circulating between the recovery water tank and the cooling water tank flows, and a system
- a power detector that detects power supply from a power source to the fuel cell system, and a temperature of water provided in at least one of the cooling water path, the cooling water tank, the recovered water tank, and the water circulation path.
- a temperature detector to detect and a temperature detected by the temperature detector when detecting a change from a state in which the power source detector is not supplied with power to a state in which power is supplied.
- the and a controller configured to perform a Atsushi Nobori process of raising the temperature above a predetermined temperature.
- microorganisms such as fungi contained in the recovered water can be sterilized by heating, and the growth of microorganisms can be suppressed as compared with the conventional fuel cell system.
- the microorganisms when the power is supplied to the fuel cell system from the state where the power is not supplied to the fuel cell system, the microorganisms are heated and sterilized, so that the conventional fuel cell Microbial growth can be suppressed more than the system.
- FIG. 1 is a block diagram schematically showing a schematic configuration of a fuel cell system according to Embodiment 1 of the present invention.
- FIG. 2 is a block diagram schematically showing electrical connection of the fuel cell system shown in FIG.
- FIG. 3 is a flowchart schematically showing a temperature raising operation in the fuel cell system according to the second embodiment.
- FIG. 4 is a flowchart showing a specific operation of the temperature raising process shown in FIG.
- FIG. 5 is a flowchart schematically showing a temperature raising operation in the fuel cell system of the first modification.
- FIG. 6 is a block diagram schematically showing a schematic configuration of the fuel cell system according to Embodiment 3 of the present invention.
- FIG. 1 is a block diagram schematically showing a schematic configuration of a fuel cell system according to Embodiment 1 of the present invention.
- FIG. 2 is a block diagram schematically showing electrical connection of the fuel cell system shown in FIG.
- FIG. 3 is a flowchart schematically showing a temperature raising operation in
- FIG. 7 is a flowchart schematically showing a temperature raising operation in the fuel cell system according to the third embodiment.
- FIG. 8 is a block diagram schematically showing a schematic configuration of the fuel cell system of the first modification.
- FIG. 9 is a flowchart schematically showing a temperature raising operation in the fuel cell system according to the first modification.
- FIG. 10 is a flowchart schematically showing a temperature raising operation in the fuel cell system of the second modification.
- FIG. 11 is a block diagram schematically showing a schematic configuration of the fuel cell system according to Embodiment 4 of the present invention.
- FIG. 12 is a flowchart schematically showing a temperature raising operation in the fuel cell system according to the fourth embodiment.
- a fuel cell system is a fuel cell system including a fuel cell, and includes a cooling water path through which cooling water for cooling the fuel cell flows, and cooling water provided in the cooling water path.
- a cooling water tank that stores water
- a recovery water tank that stores water generated in the fuel cell system
- a water circulation path through which water circulates between the recovery water tank and the cooling water tank, and power supply from the system power supply to the fuel cell system
- the power detector to detect, the temperature detector to detect the temperature of the water provided in at least one of the cooling water path, the cooling water tank, the recovered water tank, and the water circulation path, and the power detector are powered. It is configured to execute a temperature raising process for raising the temperature detected by the temperature detector to a predetermined temperature or higher when a change from a state where no power is supplied to a state where power is supplied is detected. Includes a control vessel, the.
- the state where power is not supplied refers to a state where power supply from the system power supply to the fuel cell system is stopped.
- Examples of the case where the supply of power from the system power supply to the fuel cell system is stopped include, for example, a case where wiring for supplying power to the fuel cell system is disconnected, a case where a breaker is interrupted, and a fuel cell system This may be the case when the outlet is unplugged.
- the state in which power is not supplied to the fuel cell system includes a case where the fuel cell system is stopped for a long time with water remaining in the fuel cell system.
- the bacterium is a concept including bacteria such as Escherichia coli and Bacillus subtilis and fungi such as mold.
- the predetermined temperature is a temperature at which bacteria existing in any one of the cooling water path, the cooling water tank, the recovery water tank, and the water circulation path can be sterilized (suppressing the growth of the bacteria. Temperature), which is appropriately set depending on the type of bacteria to be inhibited from growth.
- the microorganisms when power is supplied to the fuel cell system from a state where no power is supplied to the fuel cell system, the microorganisms are heated and sterilized to suppress the growth of microorganisms compared to the conventional fuel cell system. Can do.
- FIG. 1 is a block diagram schematically showing a schematic configuration of a fuel cell system according to Embodiment 1 of the present invention.
- the fuel cell system 100 includes a fuel cell 101, a cooling water path 71, a cooling water tank 102, a heater 103, a recovered water tank 104, a water circulation path 72, and a water circulator 105. , A power detector 112, a temperature detector 118, and a controller 110.
- the controller 110 raises the temperature detected by the temperature detector 118 to a predetermined temperature or more when detecting a change from a state where the power detector is not supplied with power to a state where power is supplied. It is configured to perform processing.
- the temperature raising process may be performed by operating the water circulator 105 or by operating the heater 103 and the water circulator 105.
- the fuel cell 101 has an anode 11A and a cathode 11B.
- the anode 11 ⁇ / b> A is configured to be supplied with fuel gas from the fuel gas supply device 106 via the fuel gas supply path 73.
- the cathode 11B is configured to be supplied with an oxidant gas from an oxidant gas supply unit 107 via an oxidant gas supply path 74.
- each fuel cell such as a polymer electrolyte fuel cell and a phosphoric acid fuel cell can be used. Further, since the configuration of the fuel cell 101 is the same as that of a general fuel cell, its detailed description is omitted.
- the fuel gas supply device 106 may be in any form as long as it is configured to supply fuel gas to the anode 11A of the fuel cell 101.
- the fuel gas supply device 106 may be constituted by, for example, a tank for storing fuel gas and a pump for sending fuel gas from the tank, and generates fuel gas by a reforming reaction using raw materials and water. You may be comprised with the hydrogen generator.
- the oxidant gas supply unit 107 may have any form as long as it is configured to supply the oxidant gas to the cathode 11B of the fuel cell 101.
- a fan such as a blower or a sirocco fan is used. Can be used.
- the fuel gas supply device 106 or the oxidant gas supply device 107 may include a humidifier that humidifies the supplied gas.
- the fuel gas supplied to the anode 11A and the oxidant gas supplied to the cathode 11B react electrochemically to generate water and generate electricity and heat.
- the generated heat is recovered by cooling water flowing through the cooling water passage 71, and the fuel cell 101 is cooled. Moreover, a part of the produced water is vaporized to humidify the reaction gas. Then, the steam obtained by humidifying the reaction gas and the generated water are discharged out of the fuel cell 101 together with the unused reaction gas.
- fuel gas off fuel gas
- water vapor and water generated that are not used in the fuel cell 101 are discharged out of the fuel cell system 100 via the off fuel gas path 75.
- oxidant gas off-oxidant gas
- water vapor a part of the oxidant gas (off-oxidant gas), water vapor, and generated water that is not used in the fuel cell 101 is discharged out of the fuel cell system 100 via the off-oxidant gas path 76.
- the water vapor that humidifies the fuel gas condenses into water while flowing through the off-fuel gas path 75.
- the water condensed in the off fuel gas path 75 and the water discharged to the off fuel gas path 75 are stored in the recovered water tank 104 as recovered water.
- the water vapor humidified with the oxidant gas condenses into water while flowing through the off-oxidant gas path 76.
- the water condensed in the off-oxidant gas path 76 and the water discharged to the off-oxidant gas path 76 are stored in the recovered water tank 104 as recovered water. Excess recovered water stored in the recovered water tank 104 is discharged out of the fuel cell system 100 from the drainage path 104A.
- water is recovered from both the off-fuel gas path 75 and the off-oxidant gas path 76, but the present invention is not limited to this.
- the fuel cell system 100 may adopt any form as long as water is recovered from at least one of the off-fuel gas path 75 and the off-oxidant gas path 76.
- a configuration may be adopted in which a condenser that promotes condensation of water vapor is provided in at least one of the off-fuel gas path 75 and the off-oxidant gas path 76.
- a condenser for example, a heat exchanger can be used.
- the fuel cell 101 is provided with a cooling water passage 71 through which cooling water for cooling the fuel cell 101 flows.
- a cooling water tank 102, a heater 103, and a delivery device 108 are provided in the middle of the cooling water path 71.
- the heater 103 is configured to raise the temperature of the cooling water in the cooling water passage 71
- any form may be used, for example, an electric heater may be used.
- the electric heater may be configured to consume surplus power generated by the fuel cell 101 (fuel cell system 100).
- the delivery device 108 may be in any form as long as it can deliver the water in the cooling water passage 71.
- a pump can be used.
- the heater 103 is disposed in the cooling water tank 102. This is because the cooling water tank 102 is configured to store the cooling water flowing through the cooling water passage 71 and supply the stored cooling water to the cooling water passage 71. By what can be considered. For this reason, the heater 103 may be disposed in the cooling water path 71 (including the cooling water tank 102) as long as the temperature of the cooling water in the cooling water path 71 can be increased. It may be arranged outside (including the cooling water tank 102). Further, the heater 103 may be disposed in the water circulation path 72 or the recovered water tank 104.
- a recovered water tank 104 is connected to the cooling water tank 102 via a water circulation path 72.
- a temperature detector 118 is provided in the recovered water tank 104.
- the temperature detector 118 may have any form as long as the temperature of the water in the recovered water tank 104 can be detected. In the first embodiment, the temperature detector 118 is provided in the recovered water tank 104, but is not limited to this.
- the temperature detector 118 may be provided in at least one of the cooling water tank 102, the cooling water path 71, the recovered water tank 104, and the water circulation path 72.
- a water circulator 105 is provided in the water circulation path 72.
- the water circulator 105 is configured to circulate water between the recovered water tank 104 and the cooling water tank 102.
- a pump may be used, and an open / close valve that allows / blocks the flow of water in the pump and the water circulation path 72 may be used.
- a purifier 109 is provided in a path from the recovered water tank 104 to the cooling water tank 102 in the water circulation path 72.
- the purifier 109 may have any form as long as it can purify water. In the first embodiment, it is constituted by a casing filled with an ion exchange resin, and impurities (mainly ions) contained in water are adsorbed on the ion exchange resin to be purified.
- the purifier 109 you may be comprised with the housing
- FIG. 2 is a block diagram schematically showing electrical connection of the fuel cell system shown in FIG.
- An interconnection point 114 is connected to the fuel cell 101 via a wiring 80.
- a grid power supply 111 is connected to the interconnection point 114 via a wiring 81.
- the external power load 113 is connected to the interconnection point 114 via the wiring 82.
- the auxiliary equipment (internal power load) is connected to the wiring 80 via the wiring 83.
- the auxiliary machine is a device that uses electric power among the devices constituting the fuel cell system 100.
- the controller 110, the oxidant gas supply device 107, the water circulator 105, the delivery device 108, and the like correspond thereto.
- the external power load 113 for example, an electric device used at home can be cited.
- a circuit breaker 115 is provided on the interconnection point 114 side of the portion of the wiring 80 where the wiring 83 is connected.
- the circuit breaker 115 is configured to interrupt the electrical connection between the system power supply 111 and the fuel cell system 100.
- an output controller 116 is provided closer to the fuel cell 101 than the portion of the wiring 80 to which the wiring 83 is connected.
- the output controller 116 includes, for example, at least one of a DC / DC converter and a DC / AC inverter, and the power generated by the fuel cell 101 is supplied to the external power load 113 and the auxiliary machine. It is configured as follows.
- the output controller 116 includes a power supply detector 112.
- the power supply detector 112 adds a phase variation to the function of detecting the AC voltage of the system power supply 111 and the output current of the inverter, thereby changing the phase of the voltage waveform. And a function of detecting
- the power detector 112 is configured to output the detected voltage value and the phase of the voltage waveform to the power determiner 110 a of the controller 110. And in the power supply determination device 110a, it is determined whether the power failure of the fuel cell system 100 has occurred based on the voltage value and the phase of the voltage waveform input from the power supply detector 112, and based on the voltage value, It is determined whether or not the power failure of the fuel cell system 100 has been eliminated.
- the power detector 112 and the power determiner 110a constitute a power detector.
- the power source determination unit 110a can determine that a power failure has occurred in the fuel cell system 100 when the voltage value detected by the power source detector 112 becomes equal to or less than the threshold value V1.
- the predetermined threshold value V1 can be set as appropriate.
- the power detector 112 adds a phase variation to the output current of the output controller 116, detects the phase of the voltage waveform at that time, and outputs it to the power determiner 110a.
- the power source determiner 110a can determine that a power failure has occurred in the fuel cell system 100 based on this phase change.
- the power supply determination unit 110a can determine that the power failure of the fuel cell system 100 has been resolved when the voltage value detected by the power supply detection unit 112 is equal to or greater than the predetermined threshold value V2.
- the predetermined threshold value V2 can be set as appropriate.
- the controller 110 has a power supply determiner 110a.
- the controller 110 may be in any form as long as it is a device that controls each device constituting the fuel cell system 100.
- the arithmetic processor 10a exemplified by a microprocessor, a CPU, etc.
- a storage device 10b configured of a memory or the like that stores a program for executing each control operation is provided (see FIG. 1).
- the power supply determination device 110a is implement
- the controller 110 is not only configured as a single controller, but also configured as a group of controllers that execute control of the fuel cell system 100 in cooperation with a plurality of controllers. It doesn't matter.
- the controller 110 may control the heater 103 and the water circulator 105, and may be configured such that another device controls the other devices that configure the fuel cell system 100.
- the controller 110 may be configured by a microcontroller, and may be configured by an MPU, a PLC (Programmable Logic Controller), a logic circuit, or the like.
- the fuel gas supply unit 106 operates to supply fuel gas to the anode 11A of the fuel cell 101. Further, the oxidant gas supply unit 107 is operated to supply the oxidant gas to the cathode 11B of the fuel cell 101.
- the fuel gas supplied to the anode 11A and the oxidant gas supplied to the cathode 11B react electrochemically to generate water and generate electricity and heat.
- the generated electricity is supplied to an external power load by an output controller (not shown).
- the generated heat is recovered by the cooling water flowing through the cooling water passage 71, and the fuel cell 101 is cooled. Further, the water vapor in the unused reaction gas and the generated water are recovered in the recovered water tank 104.
- bacteria may enter from the air opening of the off-fuel gas path 75 or the off-oxidant gas path 76, the outlet of the drainage path 104A of the recovered water tank 104, or the like. Then, if the invading bacteria grow in the recovered water tank 104 or the water circulation path 72, the water supply path or the narrowing of the water circulation path 72 may occur, thereby impairing the water supply function or the purification function. There is.
- the power supply 111 stops and power supply to the fuel cell system 100 is stopped (when a power failure occurs in the fuel cell system 100)
- a temperature increase process is performed to increase the temperature of the recovered water. Since it is not possible, the possibility that the bacteria will grow increases.
- the heater 103 when the power detector detects a power failure of the fuel cell system 100 and then detects that the power failure of the fuel cell system 100 has been resolved, the heater 103 And the water circulator 105 is operated so as to execute a temperature raising process for raising the temperature of the recovered water in the recovered water tank 104 to a predetermined temperature or higher.
- the controller 110 in the case where the main purpose is sterilization of fungi (for example, Neosartoria puedofischeri ) as the fungus, the controller 110 includes the cooling water tank 102.
- the amount of operation of the heater 103 and the water circulator 105 is controlled so that the temperature of the cooling water inside is about 70 ° C. and the temperature of the recovered water in the recovered water tank 104 is 45 ° C. or more.
- the vessel 110 controls the water circulator 105 to operate intermittently, and controls the water circulator 105 to stop at the end of the temperature raising process.
- the controller 110 employs a configuration in which the water circulator 105 is controlled to operate intermittently, but is not limited thereto, and the voltage value and current supplied to the water circulator 105 are not limited thereto.
- a mode in which the flow rate of water flowing through the water circulation path 72 is controlled by the water circulator 105 by changing the value, frequency, duty ratio, or the like may be adopted.
- the length of time for performing the temperature raising process by operating the heater 103 and the water circulator 105 is such that the recovered water is sterilized by heating, so that the water is blocked due to the blockage or narrowing of the channel in the water circulation path 72. It is possible to set the time appropriately so that the amount of bacteria can be reduced to such an extent that the supply function and the purification function of the purifier 109 are not impaired. More specifically, considering that the higher the temperature of the recovered water in the recovered water tank 104, the greater the heat sterilization effect, the temperatures in the cooling water tank 102 and the recovered water tank 104 (operation amount of the heater 103), etc. Based on the configuration and operating conditions of the fuel cell system 100, the time for performing the temperature raising process is set, and in the first embodiment, it is set to 2 hours.
- the temperature of the recovered water is raised by supplying the recovered water tank 104 with the cooling water that has been heated by the heater 103.
- the temperature above a predetermined temperature By raising the temperature above a predetermined temperature, the growth of bacteria contained in the recovered water can be suppressed.
- the heat-resistant temperature of the ion exchange resin is relatively low.
- the tendency is remarkable.
- Neosartria pseudofischeri was cited as a bacterium to be sterilized.
- the present invention is not limited to this, and other bacteria may be sterilized, and a plurality of bacteria may be sterilized. It is good.
- the power supply determination unit 110a determines that a power failure has occurred in the fuel cell system 100 based on the voltage value and the phase of the voltage waveform input from the power supply detector 112, and When it is determined that the power failure of the fuel cell system 100 has been resolved based on the voltage value, the water circulator 105 is operated during power generation of the fuel cell 101 after the power failure is resolved, and the amount of heat generated by the fuel cell is determined. It may be used to control so as to execute a temperature raising process for raising the temperature of the water in the recovered water tank 104 to a predetermined temperature or higher.
- the same effect as in the first embodiment can be obtained without using a heater, and a configuration without a heater may be used.
- Embodiment 2 The fuel cell system according to Embodiment 2 of the present invention is configured such that the controller executes the temperature raising process when the state where power is not supplied to the fuel cell system continues for the first predetermined time or longer. This is an example of the embodiment.
- FIG. 3 is a flowchart schematically showing a temperature raising operation in the fuel cell system according to the second embodiment.
- the controller 110 determines whether or not the power detector has detected a state in which power is not supplied to the fuel cell system 100 (step S11). Specifically, the determination is made based on whether or not the power supply determiner 110a determines that the power is not supplied to the fuel cell system 100.
- the controller 110 does not detect a state in which the power supply detector does not supply power to the fuel cell system 100 (when the power supply determination unit 110a determines that power is not supplied to the fuel cell system 100). ) (No in step S11), step S11 is repeated until it is detected that no power is supplied to the fuel cell system 100. On the other hand, when the power supply detector detects that the power supply to the fuel cell system 100 is not supplied (the power supply determination device 110a determines that the power supply to the fuel cell system 100 is not supplied). If) (Yes in step S11), the process proceeds to step S12.
- step S12 the controller 110 stores in the storage device (not shown) the time when the power supply to the fuel cell system 100 is not detected.
- the controller 110 determines whether or not the power detector has detected a state in which power is supplied to the fuel cell system 100 (step S13). Specifically, the determination is made based on whether or not the power supply determiner 110a determines that the power is being supplied to the fuel cell system 100.
- controller 110 detects a state in which power is supplied to fuel cell system 100 (when power supply determiner 110a determines that power is being supplied to fuel cell system 100). (Yes in step S13), the process proceeds to step S14. Note that the controller 110 remains in step S13 until the state in which power is not supplied to the fuel cell system 100 is resolved.
- step S14 the controller 110 acquires the current time.
- the controller 110 compares the time stored in step S12 with the current time acquired in step S14, calculates a time during which no power is supplied (time T), and the time T is the first predetermined time T1. It is determined whether or not this is the case (step S15).
- the first predetermined time T1 can be arbitrarily set. For example, the bacteria grow in the recovered water tank 104 or the water circulation path 72, and the water circulation path 72 is blocked in the flow path or narrowed. It is also possible to obtain a time at which this is likely to occur by an experiment or the like in advance and set the time.
- the first predetermined time T1 may be, for example, 3 days or 1 week.
- the controller 110 ends the program as it is. Thereby, when it is judged that the growth of the bacteria has not occurred, the wasteful energy can be suppressed and the energy saving performance can be improved by not performing the useless temperature raising process.
- Step S15 when the time T is equal to or longer than the first predetermined time T1 (Yes in Step S15), the controller 110 operates the heater 103 and the water circulator 105 to execute the temperature raising process (Step S16). .
- the temperature raising process will be described in detail with reference to FIG.
- FIG. 4 is a flowchart showing a specific operation of the temperature raising process shown in FIG. Note that the operation of the temperature raising process shown in FIG. 4 is an example, and if the heater 103 and the water circulator 105 are operated to raise the temperature of the recovered water in the recovered water tank 104 to a predetermined temperature or higher, the heating is performed.
- the operation time and the amount of operation of the vessel 103 and the water circulator 105 are not limited.
- the controller 110 acquires the temperature of the recovered water from the temperature detector 118, and determines whether or not the temperature of the recovered water is equal to or higher than the first temperature (step S101).
- the first temperature can be arbitrarily set, and specifically, can be appropriately set depending on the type of bacteria to be sterilized.
- the first temperature may be, for example, 30 to 40 ° C. or 45 ° C.
- step S101 When the temperature of the recovered water is lower than the first temperature (No in step S101), the controller 110 proceeds to step S102.
- step S102 the controller 110 stops counting a timer that measures the time for performing the temperature raising process.
- step S103 the controller 110 operates the heater 103 and the water circulator 105 (step S103), and returns to step S101.
- the controller 110 repeats steps S101 to S103 until the temperature of the recovered water becomes equal to or higher than the first temperature. And the controller 110 will progress to step S104, if the temperature of collection
- step S104 the controller 110 starts counting a timer that measures the time for performing the temperature raising process. Then, the controller 110 again acquires the temperature of the recovered water from the temperature detector 118, and determines whether or not the temperature of the recovered water is equal to or higher than the second temperature (step S105).
- the second temperature can be arbitrarily set, and can be appropriately set based on the type and capacity of the ion exchange resin used in the purifier 109.
- the second temperature may be 50 ° C., for example.
- Step S105 When the temperature of the recovered water is equal to or higher than the second temperature (Yes in Step S105), the controller 110 proceeds to Step S107, and when the temperature of the recovered water is lower than the second temperature (No in Step S105). ) Proceeds to step S106.
- step S106 the controller 110 stops the water circulator 105 and the heater 103.
- step S107 the controller 110 proceeds to step S107. Thereby, the temperature rise of the recovered water is stopped, and by suppressing the excessive temperature increase of the recovered water, it is possible to suppress the deterioration of the ion exchange resin of the purifier 109 due to heat, and to suppress waste of energy, Energy saving can be improved.
- step S107 the controller 110 determines whether or not the time measured by the timer is equal to or longer than the third time.
- the third time can be set as appropriate, and is calculated based on the D value of the target bacteria (temperature increase time required to reduce the number of bacteria to 1/10 at a constant temperature). Also good.
- a time that can be reduced to an amount of bacteria that does not impair the water supply function of the water circulator 105 and the water purification function of the purifier 109 is obtained in advance through experiments and the time is set as the third time. May be.
- step S107 When the time measured by the timer is less than the third time (No in step S107), the controller 110 returns to step S101, and the time measured by the timer is equal to or greater than the third time. Steps S101 to S107 are repeated until. On the other hand, when the time measured by the timer is equal to or longer than the third time (Yes in step S107), the controller 110 proceeds to step S108.
- step S108 the controller 110 stops the water circulator 105 and the heater 103, and then ends this program.
- the fuel cell system 100 by performing the temperature rising process at an appropriate timing, it is possible to suppress the growth of bacteria and not to perform a wasteful temperature rising process. It is possible to suppress energy waste and improve energy saving.
- the time T in a state where no power is supplied to the fuel cell system 100 is calculated, and when the time T is equal to or longer than the first predetermined time T1, the heat treatment is performed.
- the controller 110 detects not only the time when the power is not supplied, but also the temperature when the power is not supplied (the temperature in the fuel cell system 100 may be used). (It may be the temperature outside the fuel cell system 100) t is also stored, and in step S15, when the time T is equal to or longer than the first predetermined time T1 and the temperature t is within the predetermined temperature range t1, You may be comprised so that a temperature rising process may be performed.
- the controller 110 detects the temperature at which power is supplied in step S14 (the temperature may be the temperature inside the fuel cell system 100 or the temperature outside the fuel cell system 100). t is detected, and the temperature rises when the time T is equal to or longer than the first predetermined time T1 and the temperature t when the power supply is detected is within the predetermined temperature range t1 in step S15. You may be comprised so that a process may be performed. Further, in step S15, the controller 110 detects the temperature t when the time T is not less than the first predetermined time T1 and the power is not supplied, and the temperature t when the power is supplied. May be configured to perform the temperature raising process when the temperature is in the range of the predetermined temperature region t1.
- the second temperature and the third time T3 are calculated based on the D value and Z value of the target bacteria (temperature increase temperature difference required to change the D value to 1/10 or 10 times). May be.
- the target bacteria is not limited to one type, and may be a plurality of types of bacteria.
- the second temperature and the third time T3 may be calculated based on the D value and the Z value of the most severe sterilizing conditions, and the average value of the D value and the Z value in these bacteria is calculated. May be.
- the controller is configured to perform the temperature raising process every second predetermined time, and the power is not supplied from the power detector.
- the temperature increase process is executed and the power supply detector is supplied with power. Even when a change from a state where there is no power to a state where power is supplied is detected, if the time elapsed since the previous temperature increase process is less than the second predetermined time, the temperature increase process is not performed. It is an example of a configured aspect.
- the controller 110 is configured to perform the temperature raising process every second predetermined time T2.
- the second predetermined time T2 can be arbitrarily set.
- the bacteria grow in the recovered water tank 104 or the water circulation path 72, and the water circulation path 72 is blocked in the flow path or narrowed. It is also possible to obtain a time at which this is likely to occur by an experiment or the like in advance and set the time.
- the second predetermined time T2 may be, for example, 3 days or 1 week.
- FIG. 5 is a flowchart schematically showing a temperature raising operation in the fuel cell system of the first modification.
- the controller 110 determines whether or not the power detector has detected a state in which power is not supplied to the fuel cell system 100 (step S201).
- the controller 110 is in a state in which power is not supplied to the fuel cell system 100. Step S201 is repeated until is detected.
- the controller 110 proceeds to step S202.
- step S202 the controller 110 determines whether or not the power detector has detected a state in which power is supplied to the fuel cell system 100.
- the controller 110 proceeds to step S203. Note that the controller 110 remains in step S202 until the state where power is not supplied to the fuel cell system 100 is resolved.
- step S203 the controller 110 acquires the current time.
- the controller 110 calculates the time (time TA) elapsed from the previous temperature raising process from the time when the temperature raising process was performed last time and the current time acquired in step S14, and the time TA is equal to or greater than the second predetermined time T2. Is determined (step S204).
- the controller 110 ends the program as it is. Thereby, when it is judged that the growth of the bacteria has not occurred, the wasteful energy can be suppressed and the energy saving performance can be improved by not performing the useless temperature raising process.
- Step S204 when the time TA is equal to or longer than the second predetermined time T2 (Yes in Step S204), the controller 110 operates the heater 103 and the water circulator 105 to execute the temperature raising process (Step S205). . Since the temperature raising process is performed in the same manner as in the second embodiment, detailed description thereof is omitted.
- the fuel cell system according to Embodiment 3 of the present invention further includes a water level detector provided in at least one of the recovered water tank and the cooling water tank, and the controller is powered by the power detector.
- a temperature rise process is executed and the power source detector is supplied with power. Even when a change from a state where there is no power to a state where power is supplied is detected, if the water level detected by the water level detector is less than the first water level, the temperature raising process is not performed. It illustrates an embodiment.
- FIG. 6 is a block diagram schematically showing a schematic configuration of the fuel cell system according to Embodiment 3 of the present invention.
- the fuel cell system 100 according to the fourth embodiment of the present invention has the same basic configuration as the fuel cell system 100 according to the first embodiment, but a water level detector is provided in the recovered water tank 104.
- the difference is that 104B is provided.
- the water level detector 104B may have any configuration as long as it can detect the water level in the recovered water tank 104.
- a float-type water level sensor can be used.
- FIG. 7 is a flowchart schematically showing a temperature raising operation in the fuel cell system according to the third embodiment.
- the controller 110 determines whether or not the power detector has detected a state in which power is not supplied to the fuel cell system 100 (step S21).
- the controller 110 is in a state in which power is not supplied to the fuel cell system 100. Step S21 is repeated until is detected.
- the controller 110 proceeds to step S22.
- step S22 the controller 110 determines whether or not the power detector has detected a state in which power is supplied to the fuel cell system 100. If the power supply detector detects that the power is being supplied to the fuel cell system 100 (Yes in step S22), the controller 110 proceeds to step S23. Note that the controller 110 remains in step S22 until the state in which power is not supplied to the fuel cell system 100 is resolved.
- the controller 110 determines whether or not the water level detector 104B has detected the first water level.
- the first water level can be arbitrarily set as the first water level.
- the first water level is a water level where water is present in the recovered water tank 104.
- the first water level may be, for example, 1/3 of the height h of the recovered water tank 104, 1/2, or 2/3.
- the controller 110 ends this program.
- the controller 110 ends this program.
- the controller 110 ends this program.
- it can be considered that there is no water in the water circulation path 72, and the passage of the water circulation path 72 or the narrowing of the flow path does not occur due to the growth of bacteria. Because. For this reason, it is possible to prevent unnecessary temperature increase processing from being performed, and energy saving can be improved.
- step S23 the controller 110 executes a temperature raising process (step S23) and ends the program.
- the temperature rising process of step S24 is the same as the temperature rising process in Embodiment 2, the detailed description is abbreviate
- the fuel cell system 100 according to the third embodiment has the same effects as the fuel cell system 100 according to the second embodiment. Moreover, in the fuel cell system 100 according to the third embodiment, it is possible to prevent unnecessary temperature increase processing from being performed, and energy saving can be improved.
- the water level detector is provided in the recovered water tank 104.
- the present invention is not limited to this, and the water level detector may be provided in the cooling water tank 102. It is good also as a structure which provides a water level detector in both the tank 102 and the recovery water tank 104. FIG.
- the fuel cell system of Modification 1 in Embodiment 3 further includes a water supply device that supplies water to the tank in which the water level detector is provided, and the controller detects the water level detected by the water level detector as the first level.
- the water supply device When the water level is lower than the water level, the water supply device is operated, and after the temperature becomes equal to or higher than the first water level, the temperature increasing process is executed.
- FIG. 8 is a block diagram schematically showing a schematic configuration of the fuel cell system of the first modification.
- the fuel cell system 100 of Modification 1 has the same basic configuration as the fuel cell system 100 according to Embodiment 3, but a water supply device 119 that supplies water to the recovered water tank 104. Is different in that is connected.
- the water feeder 119 is connected to the recovered water tank 104 via the water supply path 79.
- the water supply device 119 is connected to, for example, a water pipe or a water tap (not shown), and supplies water (here, tap water) to the recovered water tank 104 via the water supply path 79.
- a flow rate adjustment valve, an on-off valve, and a pump can be used.
- recovery water tank 104 was employ
- a form in which the water supply device 119 is connected to the water circulation path 72 may be adopted, or a form in which the water supply device 119 is connected to the cooling water tank 102 may be adopted.
- the water feeder 119 may use a cartridge tank that stores water therein.
- FIG. 9 is a flowchart schematically showing a temperature raising operation in the fuel cell system according to the first modification.
- the temperature raising operation in the fuel cell system 100 of the first modification is the same as that of the fuel cell system 100 according to the third embodiment, but the water level detector 104B is activated in step S23. The operation when the first water level is not detected is different.
- the controller 110 operates the water supply device 119 to supply water to the recovered water tank 104. (Step S23A). And the controller 110 will perform a temperature rising process, when the water level detector 104B detects a 1st water level (it is Yes at step S23) (step S24). The controller 110 stops the water supply device 119 when the water level detector 104B detects the first water level.
- the fuel cell system of Modification 2 further includes a water supply device that supplies water to a tank in which a water level detector is provided, and the controller detects the water level detected by the water level detector below the first water level.
- a mode in which the water heater is operated to become the first water level or higher and the temperature raising process is executed after the third predetermined time has elapsed is illustrated.
- the configuration of the fuel cell system 100 of the second modification in the third embodiment is the same as the configuration of the fuel cell system 100 according to the third embodiment, the description thereof is omitted.
- FIG. 10 is a flowchart schematically showing a temperature raising operation in the fuel cell system of the second modification.
- the temperature raising operation in the fuel cell system 100 of Modification 2 is the same as that of the fuel cell system 100 according to Embodiment 3, but the water level detector 104B is activated in Step S23. The operation when the first water level is not detected is different.
- Step S23A when the water level detector 104B does not detect the first water level (No in step S23), the controller 110 operates the water supply device 119 to supply water to the recovered water tank 104.
- the controller 110 activates the water supply device 119, and when the water level detector 104B detects the first water level (Yes in step S23B), the controller 110 causes the timer (not shown) to start measuring time (step S23C). The controller 110 stops the water supply device 119 when the water level detector 104B detects the first water level.
- the controller 110 determines whether or not the time TB that has elapsed since the start of time measurement in step S23C has passed the third predetermined time (step S23D).
- the third predetermined time can be arbitrarily set. For example, bacteria grow in the recovered water tank 104 or the water circulation path 72, and the water circulation path 72 is blocked by a flow path or narrowed. A time at which there is a possibility may be obtained in advance by an experiment or the like, and the time may be set.
- the third predetermined time T3 may be, for example, 3 days or 1 week.
- step S23D When the time TB has not passed the third predetermined time T3 (No in step S23D), the controller 110 performs step S23D until the third predetermined time T3 has passed (until the third predetermined time T3 or more). repeat. Since the water supplied by the water feeder 119 is tap water, it contains a chlorine component. For this reason, the more the amount of water supplied to the recovered water tank 104, the more the growth of bacteria can be suppressed. Therefore, until the third predetermined time elapses, it is possible to suppress the growth of bacteria without performing the temperature increasing process, and to suppress unnecessary temperature increasing process, thereby improving energy saving. Can do.
- step S24 when the time TB becomes equal to or longer than the third predetermined time T3 (Yes in step S23D), the controller 110 operates the heater 103 and the water circulator 105 to execute the temperature raising process (step S24).
- the fuel cell system according to Embodiment 4 of the present invention includes a storage device that stores whether or not draining of the fuel cell system has been performed, and when the controller has not performed draining, the temperature increasing process is performed.
- FIG. 8 illustrates an embodiment configured to perform
- draining the fuel cell system means discharging the water in the cooling water tank, the recovered water tank, and the water circulation path out of the fuel cell system from the drainage channel by opening the drain valve.
- water filling of the fuel cell system means supplying water to any one of the cooling water tank, the recovered water tank, and the water circulation path.
- FIG. 11 is a block diagram schematically showing a schematic configuration of the fuel cell system according to Embodiment 4 of the present invention.
- the basic configuration of the fuel cell system 100 according to Embodiment 4 of the present invention is the same as that of the fuel cell system 100 according to Embodiment 1, but city water is supplied to the recovered water tank 104.
- the water supply path 77 for supply is provided
- the drainage path 78 is provided in the middle of the water circulation path 72
- the drainage valve 117 is provided in the middle of the drainage path 78.
- the drain valve 117 may be in any form as long as it allows / blocks the flow of water in the drainage channel 78.
- a valve such as a manual valve or an electromagnetic valve can be used. Then, in the storage device 10b of the controller 110, whether or not the fuel cell system 100 is drained is stored.
- the storage device 10b when the arithmetic processor 10a performs draining of the fuel cell system 100, the execution of draining is stored. Further, when the water filling of the fuel cell system 100 is executed, the memory for executing the water draining is deleted.
- the water supply path 77 is connected to the recovered water tank 104.
- the present invention is not limited to this, and the water purified by the purifier 109 is cooled by being connected to the water circulation path 72. It may be configured to be supplied to the water tank 102.
- the drainage channel 78 is configured to be connected in the middle of the water circulation channel 72, the drainage channel 78 is not limited thereto, and may be configured to be connected to the cooling water tank 102 or the recovered water tank 104.
- FIG. 12 is a flowchart schematically showing a temperature raising operation in the fuel cell system according to the fourth embodiment.
- steps S31 and S32 are the same as steps S21 and S22 in the temperature raising operation in the third embodiment.
- the operation after that is different.
- the controller 110 memorizes that the fuel cell system 100 has been drained when the power detector detects a state in which power is not supplied to the fuel cell system 100. It is determined whether it is stored in the container 10b.
- the storage device 10b stores the fact that the fuel cell system 100 has been drained. (When it is detected that the power is not supplied to the fuel cell system 100, the fuel cell system 100 is drained and then not filled with water) (No in step S33). Exit the program. This is because when there is no water in the recovered water tank 104 or the like, the passage of the water circulation path 72 is not blocked or narrowed due to the growth of bacteria. For this reason, it is possible to prevent unnecessary temperature increase processing from being performed, and energy saving can be improved.
- step S34 the temperature raising process is executed (step S34), and this program is terminated.
- the temperature rising process of step S34 is the same as the sterilization process in Embodiment 2, the detailed description is abbreviate
- the fuel cell system 100 according to the fourth embodiment has the same operational effects as the fuel cell system 100 according to the third embodiment.
- a fuel cell system includes a fuel cell, a cooling water path through which cooling water for cooling the fuel cell flows, a cooling water tank that stores cooling water provided in the cooling water path, A recovery water tank for storing water recovered from exhaust gas generated in the fuel cell system, a water circulation path through which water circulated between the recovery water tank and the cooling water tank, a cooling water path, a recovery water tank, and a water circulation path
- the heater provided in any of the above, the water circulator provided in the water circulation path, circulating the water between the recovered water tank and the cooling water tank, and operating the water circulator for a predetermined time after the power generation of the fuel cell is stopped And after the second time has elapsed from the stop of the water circulator, the heater and the water circulator are operated to perform a temperature raising process for raising the temperature of the water in the recovered water tank to a predetermined temperature or higher. Controller It is intended to illustrate embodiments comprising a.
- the fuel cell system 100 according to Embodiment 5 of the present invention has the same configuration as the fuel cell system 100 according to Embodiment 1, and therefore detailed description of the configuration is omitted. Further, the fuel cell system 100 according to the fifth embodiment has the same operation during the power generation operation as the fuel cell system 100 according to the first embodiment, but the operation after the power generation is stopped is performed as follows. This is different from the first embodiment.
- control is performed.
- the device 110 outputs a stop command for the fuel cell system 100.
- the controller 110 stops the fuel gas supply device 106 and the oxidant gas supply device 107.
- the controller 110 stops the operation of the delivery device 108 and stops the circulation of the cooling water. At this time, since the cooling water in the cooling water tank 102 recovered the exhaust heat in the fuel cell 101 during power generation of the fuel cell 101, the water in the water circulation path 72 and the recovery water tank 104 exceeds the predetermined temperature. The heat is high enough to raise the temperature.
- the controller 110 operates the water circulator 105 for a predetermined time, and then stops it.
- the water in the cooling water tank 102 is supplied to the recovered water tank 104 by flowing through the water circulation path 72, and the water in the recovered water tank 104 is cooled by flowing through the water circulation path 72. It is supplied to the water tank 102. That is, water is circulated between the cooling water tank 102 and the recovered water tank 104.
- the predetermined time refers to a time required to raise the temperature of the water in the recovered water tank 104 to a predetermined temperature or higher.
- the water temperature and the amount of water in the cooling water tank 102, The water temperature and amount of water and the operation amount of the water circulator 105 may be set as appropriate.
- the bacteria that have entered the recovered water tank 104 and the water circulation path 72 during the power generation operation of the fuel cell system 100 are stopped when the operation of the fuel cell system 100 is stopped ( By temperature sterilization at the time of power generation stop), the growth of bacteria after the operation stop can be suppressed.
- the controller 110 operates the heater 103 and the water circulator 105 after the second time has elapsed after stopping the water circulator 105 to recover the recovered water tank. Control is performed so as to execute a temperature raising process in which the recovered water in 104 is heated to a predetermined temperature or higher.
- the second time can be arbitrarily set. For example, bacteria grow in the recovered water tank 104, the water circulation path 72, etc., and the water circulation path 72 is blocked by the flow path or the flow path is narrowed. It is also possible to obtain a time at which this is likely to occur by an experiment or the like in advance and set the time.
- microorganisms such as fungi contained in the recovered water are heated using the heat stored in the cooling water after the power generation of the fuel cell 101 is stopped.
- the heat treatment is performed again after the water circulator 105 is stopped, whereby the growth of microorganisms such as fungi contained in the recovered water can be suppressed.
- the fuel cell system and the operation method thereof according to the present invention are more effective than the conventional fuel cell system by sterilizing microorganisms when the power is supplied to the fuel cell system from the state where no power is supplied to the fuel cell system. Is also useful because it can suppress the growth of microorganisms.
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Abstract
Description
[燃料電池システムの構成]
図1は、本発明の実施の形態1に係る燃料電池システムの概略構成を模式的に示すブロック図である。
次に、本実施の形態1に係る燃料電池システム100の発電運転時の動作について、図1を参照しながら説明する。なお、以下の諸動作は、制御器110が燃料電池システム100の各機器を制御することにより行われる。
実施の形態1の変形例1として、電源判定器110aが、電源検知器112から入力された電圧値及び電圧波形の位相を基に、燃料電池システム100の停電が生じたことを判定し、また、電圧値を基に、燃料電池システム100の停電が解消されたことを判定した場合、当該停電が解消後の燃料電池101の発電中に、水循環器105を動作させ、燃料電池の発熱量を利用して、回収水タンク104内の水を所定の温度以上に昇温する昇温処理を実行するように制御してもよい。
本発明の実施の形態2に係る燃料電池システムは、制御器が、燃料電池システムへの電力供給がされていない状態が第1所定時間以上継続した場合に、昇温処理を実行するように構成されている態様を例示するものである。
図3は、本実施の形態2に係る燃料電池システムにおける昇温動作を模式的に示すフローチャートである。
次に、本実施の形態2に係る燃料電池システムの変形例について、説明する。
本変形例1の燃料電池システム100では、制御器110は、第2所定時間T2毎に昇温処理を実行するように構成されている。ここで、第2所定時間T2は、任意に設定することができ、例えば、菌が回収水タンク104又は水循環経路72等で増殖して、水循環経路72が流路閉塞又は流路狭窄等が発生するおそれがある時間を予め実験等で求めておき、当該時間を設定してもよい。具体的には、第2所定時間T2は、例えば、3日であってもよく、1週間であってもよい。
本発明の実施の形態3に係る燃料電池システムは、回収水タンク及び冷却水タンクの少なくともいずれかのタンクに設けられた水位検知器をさらに備え、制御器が、電源検出器が電力供給されていない状態から電力供給されている状態への変化を検出し、かつ、水位検知器の検知する水位が第1の水位以上である場合、昇温処理を実行し、電源検出器が電力供給されていない状態から電力供給されている状態への変化を検出した場合であっても、水位検知器の検知する水位が第1の水位未満である場合、昇温処理を実行しないように構成されている態様を例示するものである。
図6は、本発明の実施の形態3に係る燃料電池システムの概略構成を模式的に示すブロック図である。
図7は、本実施の形態3に係る燃料電池システムにおける昇温動作を模式的に示すフローチャートである。
次に、本実施の形態3に係る燃料電池システムの変形例について、説明する。
図8は、本変形例1の燃料電池システムの概略構成を模式的に示すブロック図である。
図9は、本変形例1の燃料電池システムにおける昇温動作を模式的に示すフローチャートである。
本変形例2の燃料電池システムは、水位検知器が設けられているタンクに水を供給する給水器をさらに備え、制御器が、水位検知器の検知する水位が第1の水位未満である場合に、給水器を作動させ、第1の水位以上となり、第3所定時間経過後に、昇温処理を実行するように構成されている態様を例示するものである。
図10は、本変形例2の燃料電池システムにおける昇温動作を模式的に示すフローチャートである。
本発明の実施の形態4に係る燃料電池システムは、燃料電池システムの水抜きを実行したか否かを記憶する記憶器を備え、制御器が、水抜きが実行されていない場合、昇温処理を実行するように構成されている態様を例示するものである。
図11は、本発明の実施の形態4に係る燃料電池システムの概略構成を模式的に示すブロック図である。
図12は、本実施の形態4に係る燃料電池システムにおける昇温動作を模式的に示すフローチャートである。
本発明の実施の形態5に係る燃料電池システムは、燃料電池と、燃料電池を冷却するための冷却水が流れる冷却水経路と、冷却水経路に設けられた冷却水を貯える冷却水タンクと、燃料電池システムで生じる排ガスから回収される水を貯える回収水タンクと、回収水タンクと前記冷却水タンクとの間で循環する水が流れる水循環経路と、冷却水経路、回収水タンク、及び水循環経路のいずれかに設けられた加熱器と、水循環経路に設けられ、回収水タンクと冷却水タンクとの間で水を循環させる水循環器と、燃料電池の発電停止後に、水循環器を所定の時間動作させ、水循環器の停止から第2の時間経過後に、加熱器及び水循環器を動作させ、回収水タンク内の水を所定の温度以上に昇温する昇温処理を実行するように構成されている制御器と、を備える態様を例示するものである。
本発明の実施の形態5に係る燃料電池システム100は、実施の形態1に係る燃料電池システム100とその構成は同じであるため、構成についての詳細な説明は省略する。また、本実施の形態5に係る燃料電池システム100は、実施の形態1に係る燃料電池システム100と発電運転時の動作は同じであるが、その発電停止後の動作が以下のように行われる点が実施の形態1と異なる。
10b 記憶器
11A アノード
11B カソード
71 冷却水経路
72 水循環経路
73 燃料ガス供給路
74 酸化剤ガス供給路
75 オフ燃料ガス経路
76 オフ酸化剤ガス経路
77 水供給経路
78 排水路
80 配線
81 配線
82 配線
83 配線
100 燃料電池システム
101 燃料電池
102 冷却水タンク
103 加熱器
104 回収水タンク
104A 排水経路
104B 水位検知器
105 水循環器
106 燃料ガス供給器
107 酸化剤ガス供給器
108 送出器
109 浄化器
110 制御器
110a 電源判定器
111 系統電源
112 電源検知器
113 外部電力負荷
114 連系点
115 遮断器
116 出力制御器
117 排水弁
118 温度検知器
119 給水器
Claims (11)
- 燃料電池を備える燃料電池システムであって、
前記燃料電池を冷却するための冷却水が流れる冷却水経路と、
前記冷却水経路に設けられた前記冷却水を貯える冷却水タンクと、
前記燃料電池システムで生じる水を貯える回収水タンクと、
前記回収水タンクと前記冷却水タンクとの間で循環する水が流れる水循環経路と、
系統電源から前記燃料電池システムへの電力供給を検知する電源検出器と、
前記冷却水経路、前記冷却水タンク、前記回収水タンク及び前記水循環経路のうちの少なくとも1つに設けられた水の温度を検知する温度検知器と、
前記電源検出器が電力供給されていない状態から電力供給されている状態への変化を検出した場合に、前記温度検知器が検知する温度を所定の温度以上に昇温する昇温処理を実行するように構成されている制御器と、を備える、燃料電池システム。 - 前記冷却水経路、前記冷却水タンク、前記回収水タンク、及び前記水循環経路のいずれかに設けられた加熱器を備え、前記制御器は、前記昇温処理を実行する場合に、前記加熱器を動作させるように構成されている、請求項1に記載の燃料電池システム。
- 前記水循環経路に設けられ、前記回収水タンクと前記冷却水タンクとの間で水を循環させる水循環器をさらに備え、
前記制御器は、前記昇温処理を実行する場合に、前記水循環器に前記水循環経路内の水を循環させるように構成されている、請求項1又は2に記載の燃料電池システム。 - 前記所定の温度は、前記冷却水、前記冷却水タンク、前記回収水タンク、及び前記水循環経路内の少なくとも1つの水中に存在する菌を殺菌することができる温度である、請求項1~3のいずれか1項に記載の燃料電池システム。
- 前記制御器は、前記燃料電池システムへの電力供給がされていない状態が第1所定時間以上継続した場合に、前記昇温処理を実行するように構成されている、請求項1~4のいずれか1項に記載の燃料電池システム。
- 前記制御器は、第2所定時間毎に前記昇温処理を実行するように構成されていて、
前記電源検出器が電力供給されていない状態から電力供給されている状態への変化を検出し、かつ、前回の昇温処理から経過した時間が前記第2所定時間以上である場合には、前記昇温処理を実行し、
前記電源検出器が電力供給されていない状態から電力供給されている状態への変化を検出した場合であっても、前回の昇温処理から経過した時間が前記第2所定時間未満である場合には、前記昇温処理を実行しないように構成されている、請求項1~5のいずれか1項に記載の燃料電池システム。 - 前記回収水タンク及び前記冷却水タンクの少なくとも1つのタンクに設けられた水位検知器をさらに備え、
前記制御器は、前記電源検出器が電力供給されていない状態から電力供給されている状態への変化を検出し、かつ、前記水位検知器の検知する水位が第1の水位以上である場合、前記昇温処理を実行し、
前記電源検出器が電力供給されていない状態から電力供給されている状態への変化を検出した場合であっても、前記水位検知器の検知する水位が第1の水位未満である場合、前記昇温処理を実行しないように構成されている、請求項1~6のいずれか1項に記載の燃料電池システム。 - 前記水位検知器が設けられているタンクに水を供給する給水器をさらに備え、
前記制御器は、前記水位検知器の検知する水位が第1の水位未満である場合に、前記給水器を作動させ、前記第1の水位以上となった後に、前記昇温処理を実行するように構成されている、請求項7に記載の燃料電池システム。 - 前記水位検知器が設けられているタンクに水を供給する給水器をさらに備え、
前記制御器は、前記水位検知器の検知する水位が第1の水位未満である場合に、前記給水器を作動させ、前記第1の水位以上となり、第3所定時間経過後に、前記昇温処理を実行するように構成されている、請求項7に記載の燃料電池システム。 - 前記燃料電池システムの水抜きを実行したか否かを記憶する記憶器を備え、
前記制御器は、前記水抜きが実行されていない場合、前記昇温処理を実行するように構成されている、請求項1~6のいずれか1項に記載の燃料電池システム。 - 燃料電池を備える燃料電池システムの運転方法であって、
前記燃料電池システムは、
前記燃料電池を冷却するための冷却水が流れる冷却水経路と、
前記冷却水経路に設けられた前記冷却水を貯える冷却水タンクと、
前記燃料電池システムで生じる水を貯える回収水タンクと、
前記回収水タンクと前記冷却水タンクとの間で循環する水が流れる水循環経路と、
系統電源から前記燃料電池システムへの電力供給を検知する電源検出器と、
前記冷却水経路、前記冷却水タンク、前記回収水タンク及び前記水循環経路のうちの少なくとも1つに設けられた水の温度を検知する温度検知器と、を備え、
前記電源検出器が電力供給されていない状態から電力供給されている状態への変化を検出した場合に、前記温度検知器が検知する温度を所定の温度以上に昇温する昇温処理を実行する、燃料電池システムの運転方法。
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