JP5203570B2 - Output control method for fuel cell device - Google Patents

Description

  The present invention relates to a fuel cell device including a fuel cell using hydrogen gas as a fuel, and more particularly to a fuel cell device that recovers hydrogen gas that has not been used as fuel for a fuel cell and uses it as fuel for a hydrogen gas producer. The present invention relates to an output control method.

  Conventionally, a fuel cell device including a fuel cell that generates power using hydrogen gas as a fuel is known. This type of apparatus includes a hydrogen gas production device that produces hydrogen gas to be supplied to the fuel cell. The hydrogen gas production device produces hydrogen gas from a raw material gas such as methane gas. For example, hydrogen gas can be produced by reacting methane gas and water in the presence of a predetermined catalyst.

  The hydrogen gas production reaction such as the above reaction is generally an endothermic reaction that requires heat for the progress of the reaction. Therefore, the hydrogen gas producer includes a combustor for generating heat. As a combustor fuel, a mixed gas of hydrogen gas and air (oxygen gas) mixed at a predetermined air-fuel ratio is usually used.

  Hydrogen gas produced by the hydrogen gas production device is supplied to the fuel cell at a predetermined supply amount. In this type of fuel cell apparatus, not all supplied hydrogen gas is consumed by the fuel cell, but a part of the hydrogen gas passes through the fuel cell without being consumed and is discharged from the fuel cell.

  It is desirable that the hydrogen gas discharged from the fuel cell as described above is recovered and used as fuel or the like. Therefore, Patent Document 1 discloses a fuel cell device that uses recovered hydrogen gas as fuel for a combustor of a hydrogen gas production device.

Japanese Patent Application Laid-Open No. 2004-178962

  In the fuel cell device, when generating power at a predetermined output, the amount of hydrogen gas supplied from the hydrogen gas generator to the fuel cell, the amount of hydrogen gas consumed for power generation in the fuel cell, and the fuel cell Of the hydrogen gas that has not been consumed for power generation, the amount of hydrogen gas for the combustor that is recovered and used as fuel for the combustor is controlled to reach a steady state. When the output is changed in such a fuel cell device, the following problems occur.

  For example, when the output of the fuel cell is increased to the target output, the amount of hydrogen gas consumed by the fuel cell is increased, so that less hydrogen gas is recovered and used as fuel for the combustor. However, there was a risk that the fire of the combustor may extinguish due to lack of fuel. On the other hand, when the output of the fuel cell is reduced to the target output, the amount of hydrogen gas consumed in the fuel cell is reduced, so that the amount of hydrogen gas recovered and used as fuel for the combustor increases. However, excessive fuel is supplied to the combustor, which may cause overheating of the combustor.

  An object of the present invention is to provide a method of controlling the output of a fuel cell device that prevents the fire of a combustor of a hydrogen gas producer accompanying a change in the output of the fuel cell and prevents overheating.

An output control method for a fuel cell device according to the present invention includes a fuel cell that generates power using hydrogen gas as a fuel, a hydrogen gas generator that produces hydrogen gas from a raw material gas, and supplies the hydrogen gas to the fuel cell, and a fuel cell A combustor that uses at least a portion of the supplied hydrogen gas as a fuel for combustion and generates heat for use in a hydrogen gas generator; and an output regulator that adjusts the output of the fuel cell; In the output control method of the fuel cell device that controls the amount of hydrogen gas supplied from the gas producer to the fuel cell and outputs a predetermined power, when the output of the fuel cell is changed from the current output to the target output, the output regulator, in the first period, the output of the fuel cell, for the forward changing from a current output to the target output, once varied in the opposite direction, and the target output an output of the hydrogen gas production unit is a fuel cell Because can produce hydrogen gas required for, and so as not to exceed the allowable temperature of the combustor is predetermined, after the temperature of the hydrogen gas production unit has reached the threshold temperature of a predetermined hydrogen gas production unit, the In the second period, the output of the fuel cell is changed in the forward direction.

In the output control method of the fuel cell device, for example, when the output of the fuel cell is increased from the current output to the target output, the output regulator temporarily reduces the output of the fuel cell and consumes it in the fuel cell in the first period. The amount of hydrogen gas required is reduced while increasing the amount of combustion fuel in the combustor and the temperature of the hydrogen gas generator increases the output of the fuel cell to the target output. after reaching the first threshold temperature determined in advance as a maker is associated with the temperature which can be produced value, in the second period, increase the output of the fuel cell to the target output.

In the output control method of the fuel cell device, for example, when the output of the fuel cell is lowered from the current output to the target output, the output regulator temporarily increases the output of the fuel cell at the first timing, Increase the amount of hydrogen gas consumed to reduce the amount of combustion fuel in the combustor, while the temperature of the hydrogen gas producer reduces the fuel cell output to the target output, after reaching the second threshold temperature which defines a value associated with the temperature not exceeding, in the second period, reducing the output of the fuel cell to the target output.

Further, in the output control method of the fuel cell device, for example, the output regulator includes a supply hydrogen gas amount supplied from the hydrogen gas producer to the fuel cell, a power generation hydrogen gas amount consumed by the fuel cell,
The amount of combustor hydrogen gas consumed in the combustor is controlled.

In the fuel cell device output control method, the fuel cell device further includes a temperature sensor for detecting a temperature of the hydrogen gas producer, and a temperature of the hydrogen gas producer is predetermined based on a detection value of the temperature sensor. includes a temperature determination unit that determines whether a threshold value temperature, the output regulator, based on a result of the temperature determination portion, and wherein the switching from the first timing to the second timing.

The fuel cell device output control method according to the present invention further includes a gas regulator that adjusts the amount of hydrogen gas discharged from the fuel cell and supplied to the combustor in the fuel cell device. Is changed from the current output to the target output, the gas regulator calculates the target gas amount of hydrogen gas required by the combustor relative to the target output, and the hydrogen gas amount discharged from the fuel cell and the target it adjusted such that the difference between the amount of gas is small.

  In the output control method of the fuel cell device, the output adjuster adjusts at least one of current and voltage as the output of the fuel cell, for example.

  The present invention may be another aspect other than the output control method of the fuel cell device. For example, another aspect of the present invention is a fuel cell device.

  According to the output control method of the fuel cell device of the present invention, the fire of the combustor of the hydrogen gas production device accompanying the change in the output of the fuel cell can be extinguished and overheating can be prevented.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. FIG. 1 is a schematic configuration diagram of a fuel cell device 1 according to the present embodiment. The fuel cell device 1 is a stationary fuel cell device used at home and the like. The fuel cell device 1 includes a fuel cell 2, a hydrogen gas production device 3, an output regulator 4, and a control unit 5 that controls the output regulator 4.

  The fuel cell 2 is composed of a solid polymer electrolyte fuel cell, and is composed of a stack in which a plurality of single cells are stacked. Each unit cell has an anode that reacts with fuel gas (hydrogen gas) on one surface of an electrolyte membrane (for example, ion exchange membrane) and a cathode that reacts with oxidizing gas (oxygen gas) on the other surface. -It comprises an electrode assembly (Membrane-Electrode Assembly: MEA). When hydrogen gas and oxygen gas (usually air) are supplied to the fuel cell 2, a predetermined chemical reaction proceeds on the MEA of each single cell, and electricity can be taken out from the fuel cell 2.

  In the present embodiment, all hydrogen gas supplied to the fuel cell 2 reacts on the MEA and is not consumed. In other words, the fuel cell 2 is supplied with a larger amount of hydrogen gas than that required for power generation. A part of the supplied hydrogen gas does not react on the MEA and is discharged from the fuel cell 2. The discharged hydrogen gas (off-gas) is recovered and used as fuel for the hydrogen gas production device 3. Similarly, the air (oxidizing gas) supplied to the fuel cell 2 is supplied with a larger amount of oxidizing gas than the amount of oxidizing gas required for power generation in this embodiment. The oxidizing gas that has not reacted and consumed on the MEA is discharged from the fuel cell 2 as exhaust gas.

  The hydrogen gas production device 3 is an apparatus that produces hydrogen gas from a raw material gas such as methane gas. The hydrogen gas production device 3 is generally the same as an apparatus called a reformer that produces hydrogen gas by reforming methane gas. The raw material gas (methane gas) supplied to the hydrogen gas production device 3 is reformed into hydrogen gas by a predetermined reforming reaction. As a reaction for reforming methane gas to generate hydrogen gas, for example, there is a steam reforming reaction in which hydrogen gas is generated by reacting hydrogen gas with water in the presence of a predetermined catalyst. This reaction is an endothermic reaction, and in order to advance this reaction, it is necessary to maintain the inside of the hydrogen gas production device 3 in a temperature range of 500 ° C to 900 ° C. Therefore, the hydrogen gas production device 3 includes a combustor (burner) 6 for generating heat.

  The combustor 6 uses the hydrogen gas discharged and recovered without being consumed by the fuel cell 2 as fuel. The recovered hydrogen gas is mixed with air (oxidizing gas) at a predetermined ratio (air-fuel ratio) and used as fuel for the combustor 6. Note that all of the recovered hydrogen gas may be used as the fuel for the combustor 6, but at least a part of the recovered hydrogen gas may be used as the fuel for the combustor 6. Hydrogen gas produced by the hydrogen gas production device 3 is supplied to the fuel cell 2.

  In the hydrogen gas production device 3, when the amount of raw material gas supplied to the hydrogen gas production device 3 is increased in a state where a sufficient amount of heat is secured for the production of hydrogen gas, the hydrogen gas production device 3 produces it. The amount of hydrogen gas supplied from the hydrogen gas producer 3 to the fuel cell 2 also increases in correlation. Further, when the supply amount of the raw material gas supplied to the hydrogen gas production device 3 is reduced, the amount of hydrogen gas produced by the hydrogen gas production device 3 and supplied to the hydrogen gas production device 3 also decreases in correlation. Accordingly, if a sufficient amount of heat for hydrogen gas production is secured in the hydrogen gas production device 3, the amount of hydrogen gas supplied to the fuel cell 2 can be adjusted by adjusting the supply amount of the raw material gas. .

  On the other hand, if the amount of heat in the hydrogen gas production device 3 is insufficient, the hydrogen gas produced from the raw material gas is reduced, and in some cases, the hydrogen gas is not produced. Therefore, even if the raw material gas supply amount supplied to the hydrogen gas production device 3 is changed, the hydrogen gas amount supplied from the hydrogen gas production device 3 to the fuel cell 2 cannot be changed in a correlated manner. Therefore, if the amount of heat in the hydrogen gas production device 3 is insufficient, the amount of hydrogen gas supplied to the fuel cell 2 cannot be adjusted by adjusting the amount of raw material gas supplied.

  The hydrogen gas producer 3 includes a temperature sensor 7 that detects the temperature of the hydrogen gas producer 3. The temperature sensor 7 is usually installed at a location where a hydrogen gas production reaction is performed in the hydrogen gas producer 3. In another embodiment, the temperature sensor 7 may be provided at a position where the temperature of the combustor 6 is detected. The main purpose of installing the temperature sensor 6 is to grasp the temperature in the hydrogen gas production device 3 and to grasp the temperature of the combustor 6. Based on the detection value of the temperature sensor 7, it can be determined whether or not the temperature in the hydrogen gas production device 3 is a temperature suitable for the production of hydrogen gas. It can also be determined whether the temperature of the combustor 6 is within the allowable temperature range of the hydrogen gas producer 3 (combustor 6). Note that the detection value of the temperature sensor 7 is transmitted to the control unit 5 via a predetermined interface (not shown).

  The output regulator 4 is a device that regulates the output of the fuel cell 2. In this embodiment, the output regulator 4 can be comprised from the apparatus which combined the chopper and the inverter, for example, and adjusts an output current. With such a configuration, the direct current output from the fuel cell can be converted into an alternating current together with the current adjustment. According to this configuration, the output of the fuel cell 2 can be adjusted by adjusting the duty ratio. In other embodiments, the voltage may be adjusted or the power may be adjusted. The output of the output regulator 4 is supplied to a predetermined load 8.

  The control unit 5 includes an output adjustment command unit 9 that issues a command for adjusting the output of the fuel cell 2 to the output regulator 4. The output adjustment command unit 9 issues a command to the output regulator 4 in response to an output request command 11 given from the outside or from another control system or the like. The control unit 5 includes a temperature determination unit 10 that determines whether the temperature of the hydrogen gas production device 3 is a temperature suitable for the production of hydrogen gas based on the detection value of the temperature sensor 7. The output adjustment command unit 9 issues a predetermined command to the output regulator 4 based on the determination result of the temperature determination unit 10. The control unit 5 is composed of an electronic control unit, and its function is realized by a program stored in a storage medium such as a ROM being executed by the CPU. A part of the function may be configured by hardware.

  Next, the operation of the fuel cell device 1 during power generation will be described. During power generation, a raw material gas (methane gas) is supplied to the hydrogen gas producer 3 through the raw material gas supply path 12. Further, water used for the steam reforming reaction is supplied to the hydrogen gas production device 3 through the water supply path 13. The air mixed with the hydrogen gas of the fuel is supplied to the combustor 6 of the hydrogen gas producer 3 through the air supply path 14. The supply amount of these source gases, the supply amount of water, and the supply amount of air are controlled by the second control unit 15. The second control unit 15 functions upon receiving a command from the control unit 5. The temperature sensor 7 detects the temperature in the hydrogen gas production device 3 and transmits the detected value to the control unit 5.

  The hydrogen gas produced by the hydrogen gas production device 3 is supplied to the fuel cell 2 through the hydrogen gas supply path 16. The hydrogen gas supplied to the fuel cell 2 is consumed at the anode. The hydrogen gas that has not been consumed at the anode is discharged from the fuel cell 2, passes through the hydrogen gas recovery path 17, and is used as fuel for the combustor 6 of the hydrogen gas producer 3. Further, the oxidizing gas (air) is supplied to the fuel cell 2 through the oxidizing gas supply path 18. The supplied oxidizing gas (air) is consumed at the cathode, and the oxidizing gas that has not been consumed is discharged from the fuel cell 2 through the exhaust gas discharge path 19 as exhaust gas. The supply amount of the oxidizing gas (air) supplied to the fuel cell 2 is controlled by another control unit (not shown). The fuel gas and the oxidizing gas supplied to the fuel cell 2 may be humidified and supplied by a predetermined humidifier (not shown). Although not shown, cooling water is supplied from the cooler to the fuel cell 2 to prevent the fuel cell 2 from overheating.

  The output of the fuel cell 2 is adjusted by the output regulator 4. The output adjuster 4 operates based on a command from the output adjustment command unit 9 of the control unit 5 and adjusts the output of the fuel cell 2. If the output regulator 4 adjusts the output of the fuel cell 2, the amount of hydrogen gas consumed by the fuel cell 2 and the amount of hydrogen gas discharged without being consumed by the fuel cell 2 are adjusted. For example, when the output current of the fuel cell 2 is increased by the output regulator 4, the amount of hydrogen gas consumed at the anode of the fuel cell 2 increases and the amount of hydrogen gas discharged from the fuel cell 2 decreases. On the other hand, if the output of the fuel cell 2 is reduced by the output regulator 4, the amount of hydrogen gas consumed at the anode of the fuel cell 2 decreases and the amount of hydrogen gas discharged from the fuel cell 2 increases. Thus, by manipulating the output of the fuel cell 2, the amount of hydrogen gas consumed by the fuel cell 2 and the amount of hydrogen gas discharged and recovered from the fuel cell (hydrogen gas used as fuel by the combustor) Amount).

  Based on the output request command 11, the control unit 5 issues a command for adjusting the output to the output regulator 4. The control unit 5 acquires the detection value of the temperature sensor 7 of the hydrogen gas production device 3, and based on this detection value, the temperature determination unit 10 determines whether the temperature of the hydrogen gas production device 3 is a temperature suitable for the production of hydrogen gas. Judge whether or not. Further, the control unit 5 issues a command to the second control unit 15 in order to control the supply amount of the raw material gas and water supplied to the hydrogen gas producing device 3.

  In the fuel cell device 1 according to the present embodiment, the state of the hydrogen gas amount is as follows. The amount of hydrogen gas supplied from the hydrogen gas generator 3 to the fuel cell 2 (supply hydrogen gas amount) is defined as Q, and the amount of hydrogen gas consumed by the fuel cell 2 (power generation hydrogen gas amount) is defined as α. When the amount of hydrogen gas recovered without being used for power generation and used as fuel for the combustor 6 (combustor hydrogen gas amount) is β, Q = α + β + k. Here, k represents a correction amount used as necessary. Based on the demand from the load to which the output of the fuel cell 2 is supplied, the power generation hydrogen gas amount α is determined, and when the power generation hydrogen gas amount α is determined, the combustor hydrogen gas for securing the amount of heat necessary for this. The amount β is determined. By adding the correction amount k to these, the supply hydrogen gas amount Q to the fuel cell 2 is determined.

  In the fuel cell device 1 according to the present embodiment, when there is an output change request command (output request command 11) of the fuel cell 2, the output of the fuel cell 2 is first operated. In the present embodiment, control of the amount of hydrogen gas supplied to the fuel cell 2 and the amount of oxidizing gas supplied to the fuel cell 2 is performed with the operation of the output.

  By the way, when the output change of the fuel cell 2 is large, if the output of the fuel cell 2 is suddenly increased to the target output, the amount of hydrogen gas consumed in the fuel cell 2 increases, and is recovered and used as fuel for the combustor 6. The amount of hydrogen gas used is reduced. When the amount of recovered hydrogen gas decreases, the combustor 6 becomes short of fuel, and the temperature of the combustor 6 decreases. Then, the combustor 6 cannot supply heat necessary for the reforming reaction to the hydrogen gas producer 3. In some cases, the fire of the combustor 6 may be extinguished. If this happens, the hydrogen gas production device 6 cannot produce sufficient hydrogen gas, and the fuel cell 2 cannot be supplied with the amount of hydrogen gas necessary to obtain the target output.

  On the other hand, when the output change of the fuel cell 2 is large, if the output of the fuel cell 2 is lowered to the target output, the amount of hydrogen gas consumed in the fuel cell 2 is reduced, so that it is recovered and used as fuel for the combustor 6. The amount of hydrogen gas generated increases. When the amount of recovered hydrogen gas increases, the combustion of the combustor 6 becomes intense, and in some cases, the temperature of the combustor 6 exceeds the allowable temperature range. Thus, if the combustor 6 exceeds the allowable temperature range and overheats (overheat), the combustor 6 (hydrogen gas production device 3) may break down, which is a problem.

  Therefore, in the output control method of the fuel cell device 1 according to the present embodiment, when the output of the fuel cell 2 is changed from the current output to the target output, the output is output at two timings, the first timing and the second timing. Change the direction of change. Here, when the output of the fuel cell 2 is changed from the current output to the target output, the forward direction is the case where the change is directed from the current output to the target output. On the other hand, the case where the change is directed from the current output to the target output is set as the reverse direction. For example, when increasing from the current output to the target output, changing the output in the forward direction means changing the output by increasing it, and changing the output in the reverse direction means changing the output by decreasing the output. is there. Also, when lowering the current output to the target output, changing the output in the forward direction means changing the output by lowering it, and changing the output in the reverse direction means changing the output by raising the output. That is.

  When changing the output of the fuel cell 2 from the current output to the target output, the fuel cell device 1 according to the present embodiment first changes in the reverse direction at the first time. Thereafter, at the second time, the output of the fuel cell 2 is changed in the forward direction. Specifically, when the output of the fuel cell 2 is increased from the current output to the target output, the output of the fuel cell 2 is decreased in the first period. By reducing the output of the fuel cell 2, the amount of hydrogen gas consumed by the fuel cell 2 is reduced. Then, the amount of hydrogen gas discharged from the fuel cell 2 increases, and the fuel used in the combustor 6 increases. When the fuel in the combustor 6 increases, the temperature of the hydrogen gas producer 3 rises, and heat sufficient for producing hydrogen gas is stored. Thereafter, the output of the fuel cell 2 is increased to the target output. On the other hand, when the output of the fuel cell 2 is decreased from the current output to the target output, the output of the fuel cell 2 is increased at the first timing. By increasing the output of the fuel cell 2, the amount of hydrogen gas consumed by the fuel cell 2 increases. Then, the amount of hydrogen gas discharged from the fuel cell 2 decreases, and the fuel used in the combustor 6 decreases. When the fuel in the combustor 6 decreases, the temperature of the combustor 6 decreases, and overheating of the combustor 6 can be prevented. Thereafter, the output of the fuel cell 2 is lowered to the target output.

Hereinafter, the output control method of the fuel cell device 1 according to the present embodiment will be specifically described. First, in the fuel cell apparatus 1 shown in FIG. 1, the procedure for increasing the output current I ₁ of the fuel cell to the target output (target value) I ₃ will be described. FIG. 2 is a flowchart showing a procedure for increasing the output current of the fuel cell 2 to the target output. The procedure will be described with reference to FIGS.

In the fuel cell device ₁ that generates power with the output current I ₁ , the supply hydrogen gas amount Q supplied to the fuel cell 2, the power generation hydrogen gas amount α consumed by the fuel cell 2, and the recovered combustor 6 fuel As described above, Q = α + β + k between the combustor hydrogen gas amount β used in the above. When the control unit 5 obtains the output request command 11 with the content of raising the output current I ₁ of the fuel cell 2 to the target output I ₃ , the output adjustment command unit 9 of the control unit 5 sends the output current I to the output regulator 4. _A command to temporarily lower ₁ to I ₂ is issued (S1). The output regulator 4 operates based on the command, and lowers the output current of the fuel cell 2 from I ₁ to I ₂ (S2). When the output current of the fuel cell 2 is lowered, the amount of hydrogen gas recovered without being consumed by the fuel cell 2 increases. When the amount of hydrogen gas recovered and used as fuel for the combustor 6 increases, the temperature of the combustor 6 (temperature of the hydrogen gas production device 3) increases.

Next, the temperature sensor 7 of the hydrogen gas producer 3 detects the temperature T of the hydrogen gas producer 3 (S3). The detection value of the temperature sensor 7 is transmitted to the control unit 5. Based on the detection value of the temperature sensor 7, the temperature determination unit 10 of the control unit 5 determines whether or not the temperature T of the hydrogen gas production device 3 is equal to or higher than the threshold value m (S4). The threshold m is a temperature of the hydrogen gas production unit 3, the amount of hydrogen gas that is required between increasing the output of the fuel cell 2 to the target output I _3, associated with the temperature of the hydrogen gas production unit 3 can be prepared The predetermined value can be determined in advance.

When the temperature T of the hydrogen gas producing device 3 is equal to or higher than the threshold value m, it is determined that the temperature of the hydrogen gas producing device 3 is suitable for producing hydrogen gas. Then a command to increase the output current to the target output I ₃ from the output adjusting command unit 9 of the control unit 5 to the output controller 4 is issued (S5). On the other hand, when the temperature T of the hydrogen gas production device 3 is less than the threshold value m, the temperature of the hydrogen gas production device 3 is not determined as a temperature suitable for the production of hydrogen gas. The temperature T is detected by. Thereafter, the determination by the temperature determination unit 10 is performed again in S4.

Output controller 4 acquires an instruction to increase the output current to the target output I _3, the output controller 4 operates to increase the output current of the fuel cell 2 to the target output I ₃ (S6). Thereafter, the control unit 5 issues a command for increasing the supply amount of the raw material gas and the supply amount of water supplied to the hydrogen gas producing device 3 to the second control unit 15. When the second control unit 15 acquires the command, the supply amount of the source gas and the supply amount of water are controlled (S7). At the same time, the supply amount of air supplied to the combustor 6 of the hydrogen gas production device 3 and the supply amount of air supplied to the cathode of the fuel cell 2 are also controlled.

By the above procedure, the output current _{I 1} of the fuel cell 2 reaches the target value _{I 3} (S8). Thus, when the fuel cell generates power at the output I ₃ , the amount of hydrogen gas supplied to the fuel cell 2 (supply hydrogen gas amount Q ′) and the amount of hydrogen gas consumed by the fuel cell 2 (power generation hydrogen gas amount). α ′) and the amount of hydrogen gas recovered and used as fuel for the combustor 6 (combustor hydrogen gas amount β ′) becomes Q ′ = α ′ + β ′ + k, and power is generated with the output current I ₁ . Shift from the relationship (Q = α + β + k).

In FIG. 3A, the change in the output current of the fuel cell 2 in the procedure is shown in a graph. The vertical axis represents the output current I of the fuel cell 2, and the horizontal axis represents time t. Time _{t 1,} the output current _{I 1} of the fuel cell 2 is temporarily shows the time began to decrease to _{I 2.} Time t ₂ indicates the time in which the output current of the fuel cell 2 is started to increase to the target output I _3. Time t ₃ indicates the time when the output of the fuel cell 2 reaches the target output I ₃ . Further, in FIG. 3B, a change in the supply amount v of the raw material gas supplied to the hydrogen gas producing device 3 is shown in a graph. The vertical axis represents the raw material gas supply amount v supplied to the hydrogen gas production device 3, and the horizontal axis represents time t. The time t shown in FIG. 3 (b) is the same as the time t shown in FIG. 3 (a). When the fuel cell 2 generates electric power with the output current I ₁ , the raw material gas is supplied to the hydrogen gas producer 3 with a predetermined supply amount v ₁ . At time t _1, even if the output current of the fuel cell 2 begins to decrease, the raw material gas supply amount v ₁ is intact. At time t _2, after starting to raise the output current of the fuel cell 2 to the target output I _3, the raw material gas supply amount v supplied to the hydrogen gas production unit 3 starts to increase. When the output of the fuel cell 2 reaches the target output I _{3 at} time t ₃ , the raw material gas supply amount v supplied to the hydrogen gas production device ₃ becomes v _{3 and} becomes constant. Time t ₁ to time t ₂ are the first time, and time t ₂ to time t ₃ are the second time.

As described above, the output current I ₁ of the fuel cell 2 can be increased to the target output I ₃ without the fire of the combustor 6 of the hydrogen gas production device 3 being extinguished due to fuel shortage.

In the fuel cell apparatus 1 according to the subsequently present embodiment, the procedure for lowering the output current I ₁₁ of the fuel cell 2 to the target output (target value) I ₁₃ will be described. Figure 4 is a flowchart showing a procedure of lowering the output current I ₁₁ of the fuel cell 2 to the target output I _13. The procedure will be described with reference to FIGS.

In the fuel cell system 1 for generating an output current I _11, 'a power generation amount of hydrogen gas amount to be consumed by the fuel cell alpha' for supply of hydrogen gas amount Q 'supplied to the fuel cell 2 and' recovered combustor As described above, Q ″ = α ″ + β ″ + k between the combustor hydrogen gas amount β ″ used as the fuel No. 6. When the control unit 5 obtains the output request command 11 with the content of lowering the output current I ₁₁ of the fuel cell 3 to the target output I ₁₃ , the output adjustment command unit 9 of the control unit 5 sends an output current to the output regulator 4. the I _11, once _issues a command to raise up _{I 12} (S11). Output controller 4 which received the command operates on the basis of the instruction, increase the output current of the fuel cell 2 from _{I 11} to _{I 12} (S12). When the output current of the fuel cell 2 is increased, the amount of hydrogen gas consumed by the fuel cell 2 increases. Therefore, the amount of hydrogen gas recovered and used as fuel for the combustor 6 decreases, and the temperature of the combustor 6 (temperature of the hydrogen gas production device 3) decreases.

Next, the temperature sensor 7 of the hydrogen gas producer 3 detects the temperature T of the hydrogen gas producer 3 (S13). The detection value of the temperature sensor 7 is input to the control unit 5. The temperature determination unit 10 of the control unit 5 determines whether or not the temperature T of the hydrogen gas production device 3 is equal to or lower than the threshold value n based on the detection value of the temperature sensor 7 (S14). The threshold n is a temperature of the combustor 6, while reducing the output current of the fuel cell 2 to the target output I _13, it may be defined as a value associated with the temperature of the combustor 6 is not overheating.

When the temperature T of the hydrogen gas production device 3 is equal to or lower than the threshold value n, it is determined that the temperature of the combustor 6 has decreased to a temperature at which it does not overheat while the output current of the fuel cell 2 is decreased to the target output. Then a command to lower the output current to the target output I ₁₃ from the output instruction section 9 of the control unit 5 to the output controller 4 is issued (S15). On the other hand, when the temperature T of the hydrogen gas production device 3 exceeds the threshold value n, the temperature of the combustor 6 is not lowered to a temperature at which it does not overheat. Therefore, the process returns to S13 again from S14, and the temperature T is detected by the temperature sensor 7. Thereafter, the determination by the temperature determination unit 10 is performed again in S14.

Output controller 4 acquires an instruction to lower the output current to the target output I _13, performs operation to output controller 4 lowers the output current of the fuel cell 2 to the target output I ₁₃ (S16). Thereafter, the control unit 5 issues a command for reducing the supply amount of the raw material gas and the supply amount of water supplied to the hydrogen gas producing device 3 to the second control unit 15. If the 2nd control part 15 acquires the said instruction | command, control of the supply amount of source gas and the supply amount of water will be performed (S17). At this time, the supply amount of air supplied to the combustor 6 of the hydrogen gas production device 3 and the supply amount of air supplied to the cathode of the fuel cell 2 are also controlled.

By the above procedure, the output current _{I 11} of the fuel cell 2 reaches the target value _{I 13} (S18). Thus, when the fuel cell 2 generates power at the output I ₁₃ , the amount of hydrogen gas supplied to the fuel cell 2 (supply hydrogen gas amount Q ′ ″) and the amount of hydrogen gas consumed by the fuel cell 2 (for power generation) The relationship between the amount of hydrogen gas α ′ ″) and the amount of hydrogen gas recovered and used as fuel for the combustor 6 (combustor hydrogen gas amount β ′ ″) is Q ′ ″ = α ′ ″ + β '''+ k, and the relationship between the time of power generation by the output current I ₁₁ (Q' transition from '= α''+β''+ k).

In FIG. 5A, the change in the output current of the fuel cell 2 in the above procedure is shown in a graph. The vertical axis represents the output current I of the fuel cell 2, and the horizontal axis represents time t. Time _{t 11} is the output current _{I 11} of the fuel cell 2 is _temporarily indicating the time began to rise up to _{I 12.} Time t ₁₂ indicates the time at which the output current of the fuel cell 2 begins to decrease to the target output I _13. Time _{t 13} indicates the time at which the output of the fuel cell 2 has reached the target output _{I 13.} Further, in FIG. 5B, a change in the supply amount v of the raw material gas supplied to the hydrogen gas production device 3 is shown in a graph. The vertical axis represents the raw material gas supply amount v supplied to the hydrogen gas production device 3, and the horizontal axis represents time t. The time t shown in FIG. 5 (b) is the same as the time t shown in FIG. 5 (a). When the fuel cell 2 generates power with the output current I ₁₁ , the raw material gas is supplied to the hydrogen gas production device 3 at a predetermined supply amount v ₁₁ . Even when the output current of the fuel cell 2 starts to increase at time t ₁₁ , the raw material gas supply amount v ₁₁ remains unchanged. At time t _12, after starting to lower the output current of the fuel cell 2 to the target output I _13, the raw material gas supply amount v supplied to the hydrogen gas production unit 3 starts to decrease. When the output of the fuel cell 2 reaches the target output I _{13 at} time t ₁₃ , the raw material gas supply amount v supplied to the hydrogen gas producer 3 becomes v _{13 and} becomes constant. Note the time _{t 11} ~ time _{t 12} is a first timing, the time _{t 12} ~ time _{t 13} is a second timing.

As described above, the hydrogen combustor 6 of the gas production unit 3 without overheating, the output current I ₁₁ of the fuel cell 2 can be lowered to the target output I _13.

Hereinafter, other embodiments will be described. In the above embodiment, when the output of the fuel cell 2 is increased to the target output I ₃ , the output is once decreased, and the temperature determination unit 10 determines that the temperature of the hydrogen gas production device 3 is the hydrogen gas based on the detection value of the temperature sensor. It is determined whether or not the temperature is suitable for manufacturing, and the output is increased to the target output I ₃ based on the determination result. However, in another embodiment, the determination by the temperature determination unit 10 is performed. It does not have to be. For example, instead of the determination by the temperature determination unit 10, the output may be temporarily reduced in the above case, and the output may be increased to the target output I ₃ after a predetermined time T _{1 has} elapsed. In this case, the predetermined time T ₁ is a predetermined time, and the temperature of the hydrogen gas production device 3 is set to a temperature at which the hydrogen gas production device 3 can produce the amount of hydrogen gas required in this case. It can be determined as the time to raise. During this predetermined time T _1, once, by reducing the output, heat is ensured by the combustion of the combustor 6, the temperature in the hydrogen gas production unit 3 is increased.

Similarly, when decreasing the output of fuel cell 2 to the target output I _13, in other embodiments, once it raised the output may reduce the output after the predetermined time T ₁₁ elapses until the target output I _13. In this case, the predetermined time T ₁₁ is a predetermined time, the temperature of the hydrogen gas production unit 3, can be defined as the time down to a temperature which does not overheat. During this predetermined time T _11, once, by increasing the output, lowering the temperature of the combustor 6, combustor 6 it can be a temperature that does not overheat.

  Furthermore, as another embodiment, the fuel cell device 1 may further include a gas regulator that regulates the amount of hydrogen gas discharged from the fuel cell and supplied to the combustor. When changing the output of the fuel cell from the current output to the target output, the gas regulator calculates the target gas amount of hydrogen gas required by the combustor relative to the target output, so that it is not consumed in the fuel cell. It adjusts so that the difference of the amount of hydrogen gas discharged | emitted and the said target gas amount may become small. Thus, the amount of hydrogen gas supplied from the fuel cell to the combustor may be directly changed. For example, when the target gas amount is smaller than the amount of hydrogen gas discharged from the fuel cell, the gas regulator is discharged from the fuel cell in order to bring the amount of hydrogen gas supplied to the combustor closer to the target gas amount. Reduce the amount of hydrogen gas. Thereafter, hydrogen gas is supplied to the combustor. On the other hand, when the target gas amount is larger than the amount of hydrogen gas discharged from the fuel cell, the gas regulator uses the fuel cell to bring the amount of hydrogen gas supplied to the combustor closer to the target gas amount. Add other hydrogen gas to the discharged hydrogen gas to increase the amount. Thereafter, the increased amount of hydrogen gas is supplied to the combustor. The other hydrogen gas may be one in which the hydrogen gas generated when the gas regulator reduces the hydrogen gas discharged from the fuel cell is stored in a predetermined container or the like. You may use what is supplied more. When the fuel cell device further includes the gas regulator as described above, it is easy to change the current output to the target output.

  In other embodiments, when producing hydrogen gas from methane gas, a known reaction such as a carbon dioxide reforming reaction or a partial oxidation reforming reaction may be used in addition to the reactions shown in the above embodiment. In addition to methane gas, another raw material gas such as propane may be used. Further, liquid fuel such as methanol or gasoline may be used as a raw material for hydrogen gas.

  In the above embodiment, the control system is separated into the control unit and the second control unit. However, in other embodiments, a combination of these functions may be used. .

The schematic block diagram of the fuel cell apparatus which concerns on this embodiment is shown. It is a flowchart which shows the procedure in the case of raising the output of a fuel cell to a target output. 6 is a graph showing a change in the output of a fuel cell in the case where the output of the fuel cell is increased to a target output. (b) It is a graph which shows the change of the raw material gas supply amount supplied to a hydrogen gas manufacturing device. It is a flowchart which shows the procedure in the case of reducing the output of a fuel cell to a target output. 6 is a graph showing a change in the output of the fuel cell in the case where the output of the fuel cell is lowered to the target output. (b) It is a graph which shows the change of the raw material gas supply amount supplied to a hydrogen gas manufacturing device.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 Fuel cell apparatus, 2 Fuel cell, 3 Hydrogen gas production device, 4 Output regulator, 5 Control part, 6 Combustor, 7 Temperature sensor, 8 Load, 9 Output adjustment command part, 10 Temperature judgment part, 11 Output request command , 12 Raw material gas supply path, 13 Water supply path, 14 Air supply path, 15 Second controller, 16 Hydrogen gas supply path, 17 Hydrogen gas recovery path, 18 Oxidation gas supply path, 19 Exhaust gas discharge path.

Claims (7)

A fuel cell for generating electricity using hydrogen gas as fuel;
A hydrogen gas production device for producing hydrogen gas from raw material gas and supplying the hydrogen gas to the fuel cell;
A combustor that uses at least a portion of the hydrogen gas supplied to the fuel cell as a fuel for combustion and generates heat for use in a hydrogen gas generator;
An output regulator for regulating the output of the fuel cell;
In an output control method of a fuel cell device for controlling the amount of hydrogen gas supplied from a hydrogen gas producer to a fuel cell and outputting predetermined power,
When changing the output of the fuel cell from the current output to the target output,
The output regulator is
In the first period, the output of the fuel cell is temporarily changed in the reverse direction with respect to the forward direction in which the current output is changed to the target output.
Hydrogen Hydrogen gas production unit can be produced hydrogen gas required for the output of the fuel cell and the target output, and so as not to exceed the allowable temperature of the combustor is predetermined, the temperature of the hydrogen gas production apparatus has a predetermined after reaching the threshold temperature of the gas production unit,
An output control method for a fuel cell device, wherein the output of the fuel cell is changed in a forward direction at a second time. The output control method of the fuel cell device according to claim 1,
When raising the output of the fuel cell from the current output to the target output,
The output regulator is
In the first period, the output of the fuel cell is temporarily reduced, the amount of hydrogen gas consumed in the fuel cell is reduced to increase the amount of combustion fuel in the combustor, and the temperature of the hydrogen gas producer is changed to the output of the fuel cell. after the hydrogen gas production unit amount of hydrogen gas is required between increased to the target output reaches first threshold temperature predetermined as a value associated with the temperature capable of producing,
An output control method for a fuel cell device, wherein the output of the fuel cell is increased to a target output in a second period. The output control method of the fuel cell device according to claim 1,
When reducing the output of the fuel cell from the current output to the target output,
The output regulator is
In the first period, the output of the fuel cell is temporarily increased, the amount of hydrogen gas consumed in the fuel cell is increased to decrease the amount of combustion fuel in the combustor, and the temperature of the hydrogen gas producer is changed to the output of the fuel cell. after between lowered to the target output reaches the second threshold temperature which defines a value associated with the temperature not exceeding the allowable temperature of the combustor is predetermined, and
An output control method for a fuel cell device, wherein the output of the fuel cell is lowered to a target output in a second period. In the fuel cell device output control method according to any one of claims 1 to 3,
The output regulator is
The amount of hydrogen gas to be supplied from the hydrogen gas generator to the fuel cell;
The amount of hydrogen gas for power generation consumed by the fuel cell,
An output control method for a fuel cell device, wherein the amount of hydrogen gas for the combustor consumed in the combustor is controlled. In the output control method of the fuel cell device according to any one of claims 1 to 4,
The fuel cell device further comprises:
A temperature sensor that detects the temperature of the hydrogen gas generator;
Based on the value detected by the temperature sensor, and a temperature determination unit that the temperature of the hydrogen gas production unit to determine whether a predetermined threshold value temperature,
With
The output regulator switches from the first time to the second time based on the result of the temperature determination unit, and the output control method for the fuel cell device. In the output control method of the fuel cell device according to any one of claims 1 to 4,
The fuel cell device further includes
A gas regulator that regulates the amount of hydrogen gas discharged from the fuel cell and supplied to the combustor;
When changing the output of the fuel cell from the current output to the target output,
The gas regulator
A fuel characterized by calculating a target gas amount of hydrogen gas required by the combustor with respect to a target output, and adjusting the difference between the hydrogen gas amount discharged from the fuel cell and the target gas amount to be small Battery device output control method. In the output control method of the fuel cell device according to any one of claims 1 to 6,
The output regulator adjusts at least one of a current and a voltage as an output of the fuel cell, and controls the output of the fuel cell device.

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