JP6512047B2 - Fuel control system and control method for fuel cell system - Google Patents

Description

  The present invention relates to a wetness control device and a wetness control method of a fuel cell system for controlling the wet state of an electrolyte membrane.

  Patent Document 1 discloses a fuel cell system that controls the pressure of an oxidant supplied to a fuel cell and the flow rate of fuel circulating through the fuel cell when performing a wet operation to increase the water content of the electrolyte membrane. It is done.

Patent No. 5104950

  In the fuel cell system as described above, when performing the dry operation to reduce the water content of the electrolyte membrane, if the flow rate of fuel circulating through the fuel cell is controlled earlier than the pressure of the oxidant supplied to the fuel cell, Depending on the pressure condition of the oxidant, the water content of the electrolyte membrane may not be reduced. In such a situation, since the pressure of the oxidizing agent is unnecessarily maintained from the start of the dry operation until the fuel flow rate reaches the target value, the time required for the dry operation becomes long. There is a problem of

  The present invention has been made in view of such problems, and an object of the present invention is to provide a fuel cell system and a control method of the fuel cell system which control the wet state of the fuel cell efficiently.

  The present invention solves the above-mentioned problems by the following solutions.

  According to an aspect of the present invention, the wetness control device of the fuel cell system is provided in an oxidant system through which an oxidant for power generation of the fuel cell flows, and the oxidant supply means for supplying the oxidant to the fuel cell It includes a drainage means for discharging water generated at the electrolyte membrane of the fuel cell. Further, in the fuel cell system, a fuel flow control device of the fuel cell system is provided in a fuel system for retaining the water generated by the electrolyte membrane and circulating the fuel in the fuel system. A fuel circulating means and an oxidant system pressure adjusting means for adjusting the pressure of the oxidant system are included. Then, the wetness control device of the fuel cell system obtains at least the fuel circulation means and the oxidant system pressure adjustment by the obtaining means for obtaining a signal indicating the wet state of the electrolyte membrane and the signal obtained by the obtaining means. Control means for controlling the wet state of the electrolyte membrane. The control means controls the oxidant-based pressure control means prior to the fuel circulation means at least during a dry operation for reducing the water content of the electrolyte membrane.

  According to an aspect of the present invention, it is possible to suppress the control of the fuel circulation means in a situation where it is difficult to reduce the water content of the electrolyte membrane even if the fuel circulation means is controlled earlier than the oxidant pressure regulator. By suppressing unnecessary control in this manner, the time required for the dry operation can be shortened, so that the wet state of the fuel cell can be efficiently controlled.

FIG. 1 is a view showing the configuration of a fuel cell system according to an embodiment of the present invention. FIG. 2 is a perspective view showing an example of the configuration of a fuel cell. FIG. 3 is a cross-sectional view of the fuel cell shown in FIG. 2 taken along the line II-II. FIG. 4 is a view showing a change in water content of the electrolyte membrane by anode gas flow rate control and cathode gas pressure control. FIG. 5 is a block diagram showing an example of a functional configuration of a controller that controls the fuel cell system. FIG. 6 is a map showing the relationship between the rotational speed of the anode circulation pump and the circulation flow rate of anode gas circulating in the fuel cell. FIG. 7 is a diagram illustrating an example of a functional configuration of a membrane wet state acquisition unit that acquires a signal indicating a wet state of the electrolyte membrane. FIG. 8 is a diagram showing the relationship between the output of the fuel cell and the target electrolyte membrane wet state. FIG. 9 is a time chart showing an example of a state change of the fuel cell system when the dry operation for reducing the water content of the electrolyte membrane is performed. FIG. 10 is a block diagram showing an example of a functional configuration of a wetting control unit that controls the wet state of the fuel cell according to the second embodiment of the present invention. FIG. 11 is a block diagram showing an example of a functional configuration for calculating a target pressure of cathode gas supplied to a fuel cell. FIG. 12 is a diagram showing the relationship between the flow rate ratio of the anode gas and the cathode gas supplied to the fuel cell and the pressure difference between the electrodes. FIG. 13 is a view showing the relationship between the flow ratio of the anode gas and the cathode gas supplied to the fuel cell and the relative humidity of the cathode gas at the cathode outlet of the fuel cell. FIG. 14 is a block diagram showing an example of a functional configuration for calculating a target flow rate of anode gas supplied to a fuel cell. FIG. 15 is a block diagram showing an example of a functional configuration for calculating a target flow rate of cathode gas supplied to a fuel cell. FIG. 16 is a block diagram showing an example of a functional configuration for calculating a target pressure of anode gas supplied to a fuel cell. FIG. 17 is a flow chart showing an example of a wetness control method of the fuel cell system according to the second embodiment. FIG. 18 is a flowchart relating to a dry operation process that is performed by the method of controlling wetting of a fuel cell system. FIG. 19 is a flowchart related to the gas state adjustment process performed in the dry operation process. FIG. 20 is a time chart showing an example of a state change of the fuel cell system when the dry operation is performed. FIG. 21 is a time chart showing an example of a state change of the fuel cell system when the anode gas target pressure is calculated using the anode gas estimated flow rate instead of the anode gas target flow rate in the dry operation. FIG. 22 is a time chart showing an example of the state change of the fuel cell system when the dry operation is carried out with the drastic change of the target wet state of the electrolyte membrane. FIG. 23 is a flow chart showing an example of a wetness control method of the fuel cell system in the third embodiment. FIG. 24 is a view showing a configuration example of a measuring device for measuring the impedance of a fuel cell correlated with the wet state of the electrolyte membrane.

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

First Embodiment
FIG. 1 is a block diagram showing an example of the configuration of a fuel cell system 100 according to a first embodiment of the present invention.

  The fuel cell system 100 supplies an anode gas and a cathode gas necessary for power generation from the outside to the fuel cell, and constitutes a power supply system that generates the fuel cell according to the electrical load.

  Fuel cell system 100 includes a fuel cell stack 1, a cathode gas supply / discharge device 2, an anode gas supply / discharge device 3, a stack cooling device 4, a load device 5, an impedance measurement device 6, and a controller 200. .

  The fuel cell stack 1 is a laminated cell in which a plurality of fuel cells are laminated as described above. The fuel cell stack 1 is connected to the load device 5 to supply power to the load device 5. The fuel cell stack 1 generates a direct current voltage of, for example, several hundred volts (volts).

  The cathode gas supply / discharge device 2 constitutes an oxidant system (air system) through which the oxidant contained in the cathode gas flows. The cathode gas supply / discharge device 2 is a device that supplies the cathode gas to the fuel cell stack 1 and discharges the cathode off gas discharged from the fuel cell stack 1 to the atmosphere.

  The cathode gas supply / discharge device 2 includes a cathode gas supply passage 21, a compressor 22, a flow rate sensor 23, a cathode pressure sensor 24, a cathode gas discharge passage 25, and a cathode pressure control valve 26.

  The cathode gas supply passage 21 is a passage for supplying the cathode cell to the fuel cell stack 1. One end of the cathode gas supply passage 21 is open, and the other end is connected to the cathode gas inlet port of the fuel cell stack 1.

  The compressor 22 constitutes an oxidant supply means for supplying an oxidant to the electrolyte membrane of the fuel cell, and constitutes a drainage means for discharging water generated in the electrolyte membrane of the fuel cell by the oxidant supply means. The compressor 22 is an actuator provided in the cathode gas supply passage 21. The compressor 22 takes in air containing oxygen from the open end of the cathode gas supply passage 21 and supplies the air as a cathode gas to the fuel cell stack 1. The rotational speed of the compressor 22 is controlled by the controller 200.

  The flow rate sensor 23 is provided in the cathode gas supply passage 21 between the compressor 22 and the fuel cell stack 1. The flow rate sensor 23 detects the flow rate of the cathode gas supplied to the fuel cell stack 1. Hereinafter, the flow rate of the cathode gas supplied to the fuel cell stack 1 is simply referred to as “the cathode gas flow rate”. The flow rate sensor 23 outputs a signal obtained by detecting the cathode gas flow rate to the controller 200.

  The cathode pressure sensor 24 is provided in the cathode gas supply passage 21 between the compressor 22 and the fuel cell stack 1. The cathode pressure sensor 24 detects the pressure of the cathode gas supplied to the fuel cell stack 1. Hereinafter, the pressure of the cathode gas supplied to the fuel cell stack 1 will be simply referred to as "cathode gas pressure". The cathode pressure sensor 24 outputs a signal that detects the cathode gas pressure to the controller 200.

  The cathode gas discharge passage 25 is a passage for discharging the cathode off gas from the fuel cell stack 1. One end of the cathode gas discharge passage 25 is connected to the cathode gas outlet hole of the fuel cell stack 1, and the other end is open.

  The cathode pressure regulating valve 26 constitutes an oxidant system pressure regulation means for regulating the pressure of the oxidant system. The cathode pressure regulating valve 26 is provided in the cathode gas discharge passage 25. By changing the opening degree of the cathode pressure control valve 26, the cathode gas pressure is increased or decreased.

  As the cathode pressure regulating valve 26, for example, a solenoid valve capable of stepwise changing the opening degree of the valve is used. The cathode pressure control valve 26 is controlled by the controller 200 to open and close. The on-off control adjusts the cathode gas pressure to a desired pressure. As the opening degree of the cathode pressure regulating valve 26 becomes larger, the cathode pressure regulating valve 26 opens, and as the opening degree of the cathode pressure regulating valve 26 becomes smaller, the cathode pressure regulating valve 26 closes.

  In the anode gas supply / discharge device 3, the anode gas flows in the direction opposite to the flow of the oxidant system, and constitutes a fuel system (hydrogen system) for retaining water generated by the electrolyte membrane in the fuel cell stack 1. The anode gas supply / discharge device 3 is a device that supplies the anode gas to the fuel cell stack 1 and introduces the anode off gas discharged from the fuel cell stack 1 into the fuel cell stack 1 for circulation.

  The anode gas supply / discharge device 3 includes a high pressure tank 31, an anode gas supply passage 32, an anode pressure regulating valve 33, an ejector 34, an anode gas circulation passage 35, an anode circulation pump 36, an anode pressure sensor 37, and a purge. And a valve 38.

  The high pressure tank 31 maintains the anode gas supplied to the fuel cell stack 1 at high pressure and stores it.

  The anode gas supply passage 32 is a passage for supplying the fuel cell stack 1 with the anode gas stored in the high pressure tank 31. One end of the anode gas supply passage 32 is connected to the high pressure tank 31, and the other end is connected to the anode gas inlet hole of the fuel cell stack 1.

  The anode pressure regulating valve 33 constitutes a fuel system pressure adjusting means for adjusting the pressure of the fuel system. The anode pressure regulating valve 33 is provided in an anode gas supply passage 32 between the high pressure tank 31 and the ejector 34. By changing the opening degree of the anode pressure regulating valve 33, the pressure of the anode gas supplied to the fuel cell stack 1 is increased or decreased.

  As the anode pressure regulating valve 33, for example, a solenoid valve capable of stepwise changing the opening degree of the valve is used. The anode pressure regulating valve 33 is controlled by the controller 200 to open and close. By the on-off control, the pressure of the anode gas supplied to the fuel cell stack 1 is adjusted.

  The ejector 34 is provided in an anode gas supply passage 32 between the anode pressure regulating valve 33 and the fuel cell stack 1. The ejector 34 is a mechanical pump provided at a portion where the anode gas circulation passage 35 joins the anode gas supply passage 32.

  The anode gas circulation passage 35 is a passage for circulating the anode off gas from the fuel cell stack 1 to the anode gas supply passage 32. One end of the anode gas circulation passage 35 is connected to the anode gas outlet hole of the fuel cell stack 1, and the other end is connected to the suction port of the ejector 34.

  The anode circulation pump 36 constitutes a fuel circulation means for circulating the fuel contained in the anode gas in the anode gas circulation passage 35 of the fuel system. The anode circulation pump 36 is an actuator that adjusts the circulation flow rate of anode gas containing fuel. By changing the rotational speed of the anode circulation pump 36, the circulation flow rate of the anode gas flowing through the anode gas circulation passage 35 is increased or decreased.

  An anode circulation pump 36 is provided in the anode gas circulation passage 35. The anode circulation pump 36 circulates the anode off gas to the fuel cell stack 1 via the ejector 34. The rotational speed of the anode circulation pump 36 is controlled by the controller 200. Thereby, the flow rate of the anode gas circulating in the anode gas circulation passage 35 is adjusted. Hereinafter, the flow rate of the anode gas circulating in the fuel cell stack 1 is referred to as “anode gas circulation flow rate”.

  An anode pressure sensor 37 is provided in an anode gas supply passage 32 between the ejector 34 and the fuel cell stack 1. The anode pressure sensor 37 detects the pressure of the anode gas supplied to the fuel cell stack 1. Hereinafter, the pressure of the anode gas supplied to the fuel cell stack 1 is simply referred to as “anode gas pressure”. The anode pressure sensor 37 outputs a signal obtained by detecting the anode gas pressure to the controller 200.

  The purge valve 38 is provided in an anode gas discharge passage branched from the anode gas circulation passage 35. The purge valve 38 exhausts the impurities contained in the anode off gas to the outside. The impurities refer to nitrogen gas in the air that has permeated (leaked) the electrolyte membrane 111 from the cathode gas flow path 131, water produced by power generation, and the like. The opening degree of the purge valve 38 is controlled by the controller 200.

  The anode gas discharge passage (not shown) joins the cathode gas discharge passage 25 on the downstream side of the cathode pressure control valve 26. As a result, the anode off gas discharged from the purge valve 38 is mixed with the cathode off gas in the cathode gas discharge passage 25, so that the hydrogen concentration in the mixed gas is maintained at or below the specified value.

  The stack cooling device 4 is a device for cooling the temperature of the fuel cell 10. The stack cooling device 4 includes a cooling water circulation passage 41, a cooling water pump 42, a radiator 43, a bypass passage 44, a three-way valve 45, an inlet water temperature sensor 46, and an outlet water temperature sensor 47.

  The cooling water circulation passage 41 is a passage for circulating the cooling water to the fuel cell stack 1. One end of the cooling water circulation passage 41 is connected to the cooling water inlet of the fuel cell stack 1, and the other end is connected to the cooling water outlet of the fuel cell stack 1.

  The cooling water pump 42 is provided in the cooling water circulation passage 41. The cooling water pump 42 supplies cooling water to the fuel cell stack 1 via the radiator 43. The rotational speed of the cooling water pump 42 is controlled by the controller 200.

  The radiator 43 is provided in the cooling water circulation passage 41 downstream of the cooling water pump 42. The radiator 43 cools the cooling water warmed inside the fuel cell stack 1 by a fan.

  The bypass passage 44 is a passage that bypasses the radiator 43 and is a passage that circulates the cooling water discharged from the fuel cell stack 1 back to the fuel cell stack 1. One end of the bypass passage 44 is connected to the cooling water circulation passage 41 between the cooling water pump 42 and the radiator 43, and the other end is connected to one end of the three-way valve 45.

  The three-way valve 45 regulates the temperature of the cooling water supplied to the fuel cell stack 1. The three-way valve 45 is realized by, for example, a thermostat. The three-way valve 45 is provided at a portion where the bypass passage 44 merges in the cooling water circulation passage 41 between the radiator 43 and the cooling water inlet hole of the fuel cell stack 1.

  The inlet water temperature sensor 46 and the outlet water temperature sensor 47 detect the temperature of the cooling water. The temperature of the cooling water is used as the temperature of the fuel cell stack 1 or the temperature of the cathode gas. Hereinafter, the temperature of the fuel cell stack 1 is also referred to simply as the "stack temperature".

  The inlet water temperature sensor 46 is provided in the cooling water circulation passage 41 located in the vicinity of the cooling water inlet formed in the fuel cell stack 1. The inlet water temperature sensor 46 detects the temperature of the cooling water flowing into the cooling water inlet of the fuel cell stack 1. Hereinafter, the temperature of the cooling water flowing into the cooling water inlet hole of the fuel cell stack 1 is referred to as “stack inlet water temperature”. The inlet water temperature sensor 46 outputs a signal indicating that the stack inlet water temperature has been detected to the controller 200.

  The outlet water temperature sensor 47 is provided in the cooling water circulation passage 41 located in the vicinity of the cooling water outlet hole formed in the fuel cell stack 1. The outlet water temperature sensor 47 detects the temperature of the cooling water discharged from the fuel cell stack 1. Hereinafter, the temperature of the cooling water discharged from the fuel cell stack 1 is referred to as “stack outlet water temperature”. The outlet water temperature sensor 47 outputs a signal indicating that the stack outlet water temperature has been detected to the controller 200.

  The load device 5 receives and drives the generated power supplied from the fuel cell stack 1. The load device 5 includes, for example, an electric motor for driving a vehicle, a control unit for controlling the electric motor, and an auxiliary device for assisting the power generation of the fuel cell stack 1. As an auxiliary machine of the fuel cell stack 1, for example, a compressor 22, an anode circulation pump 36, a cooling water pump 42 and the like can be mentioned.

  The control unit that controls the load device 5 outputs the power necessary for the operation of the load device 5 to the controller 200 as the required power for the fuel cell stack 1. For example, the required power of the load device 5 increases as the depression amount of the accelerator pedal provided in the vehicle increases.

  A current sensor 51 and a voltage sensor 52 are disposed between the load device 5 and the fuel cell stack 1.

  The current sensor 51 is connected to a power supply line between the positive electrode terminal 1 p of the fuel cell stack 1 and the positive electrode terminal of the load device 5. The current sensor 51 detects the current output from the fuel cell stack 1 to the load device 5. Hereinafter, the current output from the fuel cell stack 1 to the load device 5 is referred to as “stack output current”. The current sensor 51 outputs a signal obtained by detecting the stack output current to the controller 200.

  The voltage sensor 52 is connected between the positive electrode terminal 1 p and the negative electrode terminal 1 n of the fuel cell stack 1. The voltage sensor 52 detects an inter-terminal voltage which is a voltage between the positive electrode terminal 1 p and the negative electrode terminal 1 n. Hereinafter, the voltage between terminals of the fuel cell stack 1 is referred to as "stack output voltage". The voltage sensor 52 outputs a signal obtained by detecting the stack output voltage to the controller 200.

  The impedance measuring device 6 is a device that detects the wet state of the electrolyte membrane 111. The impedance measuring device 6 measures the internal impedance of the fuel cell stack 1 correlated with the wet state of the electrolyte membrane 111.

  Generally, as the water content (water content) of the electrolyte membrane decreases, that is, as the electrolyte membrane becomes more dry, the electrical resistance component of the internal impedance increases. On the other hand, as the water content of the electrolyte membrane increases, that is, as the electrolyte membrane gets wet, the electrical resistance component of the internal impedance decreases. For this reason, in the present embodiment, the internal impedance of the fuel cell stack 1 is used as a parameter indicating the wet state of the electrolyte membrane 111.

  The fuel cell stack 1 is provided with a positive electrode tab connected in series with the positive electrode terminal 1 p and a negative electrode tab connected in series with the negative electrode terminal 1 n. The impedance measuring device 6 is provided for each of the positive electrode tab and the negative electrode tab. Is connected. The impedance measuring device 6 supplies an alternating current having a frequency suitable for detecting the electric resistance of the electrolyte membrane 111 to the positive electrode terminal 1 p. The frequency suitable for detecting the electrical resistance of the electrolyte membrane is hereinafter referred to as "electrolyte membrane response frequency". The impedance measuring device 6 detects the AC voltage generated between the positive electrode terminal 1p and the negative electrode terminal 1n by the AC current of the electrolyte membrane response frequency, and the amplitude of the detected AC voltage is supplied to the positive electrode terminal 1p. The internal impedance is calculated by dividing by.

  In the present embodiment, a midway tab is provided to the fuel cell 10 located in the middle of the fuel cell 10 stacked in the fuel cell stack 1, and the midway tab is grounded by the impedance measuring device 6. Then, the impedance measuring device 6 supplies an alternating current of the electrolyte membrane response frequency to both the positive electrode terminal 1 p and the negative electrode terminal 1 n. The impedance measuring device 6 calculates the internal impedance on the positive electrode side by dividing the amplitude of the alternating voltage between the positive electrode terminal 1 p and the midway tab by the amplitude of the alternating current supplied to the positive electrode terminal 1 p. The impedance measuring device 6 calculates the internal impedance on the negative electrode side by dividing the amplitude of the alternating voltage between the negative electrode terminal 1 n and the midway tab by the amplitude of the alternating current supplied to the negative electrode terminal 1 n.

  Below, the thing of the internal impedance measured by the electrolyte membrane response frequency is called measurement HFR (High Frequency Resistance; high frequency resistance). The impedance measuring device 6 outputs the calculated measurement HFR to the controller 200.

  The controller 200 is configured by a microcomputer provided with a central processing unit (CPU), a read only memory (ROM), a random access memory (RAM), and an input / output interface (I / O interface).

  The controller 200 includes respective output signals of the flow rate sensor 23, the cathode pressure sensor 24, the anode pressure sensor 37, the inlet water temperature sensor 46, the outlet water temperature sensor 47, the current sensor 51, the voltage sensor 52 and the impedance measuring device 6, and the load device 5. And the required power from are input. These signals are used as parameters related to the operating state of the fuel cell system 100.

  The controller 200 configures a wetness control device that controls the wet state of the fuel cell stack 1 in the fuel cell system 100. The controller 200 controls the flow rate and pressure of the cathode gas using the compressor 22 and the cathode pressure regulating valve 26 in accordance with parameters related to the operating state of the fuel cell system 100. Furthermore, the controller 200 controls the flow rate and pressure of the anode gas using the anode pressure regulating valve 33 and the anode circulation pump 36. Further, the controller 200 controls the temperature of the fuel cell stack 1 using the cooling water pump 42 and the three-way valve 45 in accordance with the parameters related to the operating state of the fuel cell system 100.

  For example, the controller 200 calculates target values of the cathode gas flow rate and pressure, and target values of the flow rate and pressure of the anode gas based on the required power of the load device 5. The controller 200 controls the rotational speed of the compressor 22 and the opening degree of the cathode pressure regulating valve 26 based on the target values of the flow rate and pressure of the cathode gas, and the anode circulation based on the target values of the flow rate and pressure of the anode gas. The rotational speed of the pump 36 and the opening degree of the anode pressure control valve 33 are controlled.

  FIGS. 2 and 3 are diagrams showing an example of the configuration of a fuel cell 10 formed in the fuel cell stack 1. 2 is a perspective view of the fuel cell 10, and FIG. 3 is a cross-sectional view of the fuel cell 10 shown in FIG.

  The fuel cell 10 is composed of an anode electrode as a fuel electrode, a cathode electrode as an oxidant electrode, and an electrolyte membrane disposed so as to be sandwiched between these electrodes. An anode gas containing hydrogen is supplied as a fuel to the anode electrode of the fuel cell. A cathode gas containing oxygen as an oxidant is supplied to the cathode electrode of the fuel cell.

  The fuel cell 10 is a cell that generates electric power using an anode gas containing hydrogen and a cathode gas containing oxygen. The electrode reactions that proceed at both the anode and cathode electrodes are as follows.

^{_{Anode: 2H 2 → 4H + + 4e}} - ··· (A)
Cathode electrode: 4H ⁺ + 4e ⁻ + O ₂ → 2H ₂ O (B)
The fuel cell 10 generates an electromotive force of about 1 V (volt) by the electrode reactions of (A) and (B).

  As shown in FIGS. 2 and 3, the fuel cell 10 includes a membrane electrode assembly (MEA) 11, and an anode separator 12 and a cathode separator 13 disposed so as to sandwich the MEA 11.

  The MEA 11 is composed of an electrolyte membrane 111, an anode electrode 112, and a cathode electrode 113. The MEA 11 has an anode electrode 112 on one side of the electrolyte membrane 111 and a cathode electrode 113 on the other side.

  The electrolyte membrane 111 is a proton conductive ion exchange membrane formed of a fluorine-based resin. The electrolyte membrane 111 exhibits good electrical conductivity with a suitable degree of wetting. The degree of wettability of the electrolyte membrane 111 mentioned here corresponds to the amount of water (water content) contained in the electrolyte membrane 111. As the wettability of the electrolyte membrane 111 becomes higher, the water content of the electrolyte membrane 111 increases to be in a wet state, and as the wettability of the electrolyte membrane 111 becomes lower, the water content of the electrolyte membrane 111 decreases to become a dry state.

  The anode electrode 112 includes a catalyst layer 112A and a gas diffusion layer 112B. The catalyst layer 112A is a member formed of carbon black particles supporting platinum, platinum or the like, and is provided in contact with the electrolyte membrane 111. The gas diffusion layer 112B is disposed outside the catalyst layer 112A. The gas diffusion layer 112 </ b> B is a member formed of carbon cloth having gas diffusivity and conductivity, and is provided in contact with the catalyst layer 112 </ b> A and the anode separator 12.

  Similarly to the anode electrode 112, the cathode electrode 113 also has a catalyst layer 113A and a gas diffusion layer 113B. The catalyst layer 113A is disposed between the electrolyte membrane 111 and the gas diffusion layer 113B, and the gas diffusion layer 113B is disposed between the catalyst layer 113A and the cathode separator 13.

  The anode separator 12 is disposed outside the gas diffusion layer 112B. The anode separator 12 includes a plurality of anode gas flow channels 121 for supplying an anode gas to the anode electrode 112. The anode gas flow passage 121 is formed as a grooved passage. That is, the anode gas flow channel 121 constitutes a fuel flow channel for passing the fuel to the other surface of the electrolyte membrane 111.

  The cathode separator 13 is disposed outside the gas diffusion layer 113B. The cathode separator 13 includes a plurality of cathode gas flow paths 131 for supplying a cathode gas to the cathode electrode 113. The cathode gas flow channel 131 is formed as a grooved channel. That is, the cathode gas flow channel 131 constitutes an oxidant flow channel through which the oxidant is passed to one surface of the electrolyte membrane 111.

  Further, the cathode separator 13 is provided with a plurality of cooling water flow paths 141 for supplying the cooling water of the fuel cell 10. The cooling water channel 141 is formed in a groove shape.

  As shown in FIG. 2, the cathode separator 13 is configured such that the flow direction of the cooling water flowing in the cooling water flow channel 141 and the flow direction of the cathode gas flowing in the cathode gas flow channel 131 are in the same direction. In addition, these flow directions may be configured to be opposite to each other, and may be configured to have a predetermined angle.

  The anode separator 12 and the cathode separator 13 are configured such that the flow direction of the anode gas flowing through the anode gas flow channel 121 and the flow direction of the cathode gas flowing through the cathode gas flow channel 131 are opposite to each other. Also, these flow directions may be configured to have a predetermined angle.

  In such a fuel cell 10, the power generation performance of the fuel cell stack 1 is reduced if the degree of wetting, which indicates the water content of each electrolyte membrane 111, becomes too high or too low. In order to efficiently generate power from the fuel cell stack 1, it is important to maintain the electrolyte membrane 111 at an appropriate degree of wetness. Therefore, the controller 200 controls the wet state of the fuel cell stack 1 so that the wet state of the fuel cell stack 1 is maintained in a state suitable for power generation within a range where the required power from the load device 5 can be secured. .

  In the following, “wet control” is performed to control the flow rate and pressure of the anode gas, and the flow rate and pressure of the cathode gas so that the wet state of the fuel cell stack 1 is maintained in a range suitable for power generation. It is said. And, in order to reduce the excess water content of the electrolyte membrane 111, the wet control to make the wet state of the fuel cell stack 1 transition to the dry side is called "dry operation". Moreover, in order to increase the water content of the electrolyte membrane 111, the control of the wet state in which the wet state of the fuel cell stack 1 is shifted to the wet side is referred to as "wet operation".

  In wetting control of the fuel cell stack 1, the controller 200 mainly controls four parameters: cathode gas flow rate, cathode gas pressure, anode gas flow rate, and anode gas pressure.

  The cathode gas flow control by the controller 200 is mainly performed using the compressor 22, and the cathode gas pressure control is mainly performed using the cathode pressure control valve 26.

  In the dry operation, the controller 200 increases the cathode gas flow rate or lowers the cathode gas pressure so that the amount of water discharged from the fuel cell stack 1 to the outside increases. On the contrary, in the wet operation, the controller 200 reduces the cathode gas flow rate and raises the cathode gas pressure. Hereinafter, control for decreasing the cathode gas pressure is referred to as "step-down control".

  The anode gas flow rate control by the controller 200 is mainly performed using the anode circulation pump 36.

  The anode gas flowing on the upstream side of the anode gas flow channel 121 shown in FIG. 2 is humidified by the water vapor leaked from the downstream side of the cathode gas flow channel 131 via the electrolyte membrane 111. Therefore, when the anode gas circulation flow rate is increased, the anode gas humidified on the upstream side of the anode gas flow passage 121 is likely to spread to the electrolyte membrane 111 on the downstream side, and the anode gas flow passage 121 and the anode gas circulation passage 35 The total amount of water vapor mixed in the circulating anode gas increases. As a result, the water content of the electrolyte membrane 111 is likely to increase.

  Therefore, the controller 200 increases the anode gas circulation flow rate so that the humidified anode gas spreads throughout the fuel cell stack 1 during the wet operation. Conversely, during dry operation, the controller 200 reduces the anode gas circulation flow rate. In the following, the wet control for reducing the anode gas circulation flow rate is referred to as "loss control".

  The anode gas pressure control by the controller 200 is mainly performed using the anode pressure regulating valve 33.

  In the dry operation, the controller 200 increases the anode gas pressure so that the amount of water vapor leaking from the cathode gas flow path 131 to the anode gas flow path 121 decreases, and in the wet operation, the anode gas pressure decreases. Let

  In such wetting control, the controller 200 executes weight reduction control for reducing the anode gas circulation flow rate and pressure reduction control for reducing the cathode gas pressure when performing the dry operation. However, if the decrease control of the anode gas is performed prior to the execution of the step-down control of the cathode gas in the dry operation, the water content of the electrolyte film 111 will not decrease or the water content of the electrolyte film 111 will increase. The inventors have found out.

  FIG. 4 is a diagram for explaining the relationship between the anode gas circulation flow rate and the cathode gas pressure. In FIG. 4, the vertical axis indicates the wet state of the fuel cell stack 1, and the horizontal axis indicates the anode gas circulation flow rate. Here, the wet state of the fuel cell stack 1 when the anode gas circulation flow rate is increased is shown for each of the "large", "medium" and "small" cathode gas pressures.

  As shown in FIG. 4, in the dry operation 1, when the cathode gas pressure is lowered from "high" to "medium" with the anode gas circulation flow rate high, the wet state of the fuel cell stack 1 transitions to the dry side . That is, the dry operation is efficiently performed by the step-down control of the cathode gas.

  On the other hand, in the dry operation 2, when the anode gas circulation flow rate is reduced when the cathode gas pressure is "high", the electrolyte membrane 111 of the fuel cell stack 1 warps and becomes wet. That is, in the dry operation, even if the decrease control of the anode gas is performed in a state where the cathode gas pressure is high, the water content of the electrolyte membrane 111 is increased without being reduced.

  As described above, when the decrease control of the anode gas is performed prior to the execution of the step-down control of the cathode gas, the time required for the dry operation may increase. On the other hand, as in the dry operation 1 shown in FIG. 4, the dry operation can be efficiently performed by lowering the cathode gas pressure before reducing the anode gas circulation flow rate.

  Therefore, when performing the dry operation, the controller 200 of the present embodiment executes the step-down control of the cathode gas with priority over the reduction control of the anode gas. That is, the controller 200 controls the operation of the cathode pressure control valve 26 prior to the operation of the anode circulation pump 36 at least during the dry operation.

  FIG. 5 is a block diagram showing an example of a functional configuration of the controller 200 in the present embodiment.

  The controller 200 wets the membrane wet state acquisition unit 210, the stack target current calculation unit 220, the anode gas circulation flow rate estimation unit 230, the cathode gas supply / discharge device command unit 240, the anode gas supply / discharge device command unit 250, and And a control unit 300.

  The membrane wet state acquiring unit 210 is an acquiring unit that acquires a signal indicating the wet state of the electrolyte membrane 111 in the fuel cell stack 1. In the present embodiment, the membrane wet state acquisition unit 210 acquires the measurement HFR from the impedance measurement device 6 as the wet state information indicating the wetness of the electrolyte membrane 111.

  The membrane wet state acquiring unit 210 calculates a target water balance for maintaining the state of the electrolyte membrane 111 in a wet state suitable for power generation based on the measured HFR from the impedance measurement device 6. The target water balance referred to here is a parameter that represents excess and deficiency of water from the target wet state of the electrolyte membrane 111, and is a parameter that is correlated with the wettability of the electrolyte membrane 111.

  For example, when the measured HFR is smaller than the target value, the membrane wet state acquiring unit 210 determines that the water content of the electrolyte membrane 111 is large, and calculates a negative (negative) value as the target water balance. If it is determined that the water content of the electrolyte membrane 111 is high, the wet control unit 300 performs a dry operation to reduce the excess water content of the electrolyte membrane 111.

  On the other hand, if the measured HFR is larger than the target value, the membrane wet state acquiring unit 210 determines that the water content of the electrolyte membrane 111 is low, and calculates a positive (positive) value as the target water balance. If it is determined that the water content of the electrolyte membrane 111 is low, the wet control unit 300 carries out a dry operation to increase the water content of the electrolyte membrane 111 in an insufficient amount.

  The membrane wet state acquiring unit 210 outputs the calculated target water balance to the wetting control unit 300.

  The membrane wet state acquisition unit 210 may generate the wet state information using the temperature of the fuel cell stack 1 instead of the measurement HFR. In this case, the membrane wet state acquiring unit 210 calculates the average value of the stack inlet water temperature and the stack outlet water temperature as the temperature of the fuel cell stack 1. Then, the membrane wet state acquiring unit 210 refers to a predetermined wet estimation map, specifies wet state information associated with the calculated temperature of the fuel cell stack 1, and based on the specified wet state information Calculate the balance.

  Alternatively, the membrane wet state acquisition unit 210 may generate wet state information based on the required power of the load device 5. In this case, when the membrane wet state acquisition unit 210 acquires the required power from the control unit of the load device 5, the wet state information associated with the acquired required power is referred to with reference to a predetermined wet estimation map. Identify. For example, as the power requirement of the load device 5 increases, the amount of generation of generated water accompanying power generation increases, so the membrane wet state acquiring unit 210 increases the degree of wetting of the electrolyte membrane 111 indicated by the wet state information.

  The stack target current calculation unit 220 calculates a stack target current based on the required power of the load device 5 connected to the fuel cell stack 1.

  For example, the IV (current-voltage) characteristic of the fuel cell stack 1 is recorded in advance in the stack target current calculation unit 220. When the stack target current calculation unit 220 acquires the required power from the load device 5, the stack target current calculation unit 220 refers to the IV characteristic stored in advance and calculates a current value associated with the acquired generated power as the stack target current. The IV characteristics of the fuel cell stack 1 may be estimated from the relationship between the stack output current and the stack output voltage when the output current of the fuel cell stack 1 is changed.

  The stack target current calculation unit 220 outputs the calculated stack target current to the wetting control unit 300.

  The anode gas circulation flow rate estimation unit 230 estimates an anode gas circulation flow rate supplied to the fuel cell stack 1 based on the operation state of the anode gas supply / discharge device 3. In the present embodiment, a flow rate estimation map indicating the relationship between the rotational speed of the anode circulation pump 36 and the anode gas circulation flow rate is recorded in advance in the anode gas circulation flow rate estimation unit 230. The flow rate estimation map will be described later with reference to FIG.

The anode gas circulation flow rate estimation unit 230 acquires the rotation speed of the anode circulation pump 36 from the rotation speed sensor provided in the anode circulation pump 36. The anode gas circulation flow rate estimation unit 230 acquires the rotational speed of the anode circulating pump 36, with reference to the flow rate estimation map, calculates the anode gas circulation flow rate Q _a which is related to the rotational speed acquired. Further, the anode gas circulation flow rate estimation unit 230 acquires the measurement value P _a of the anode gas pressure from the anode pressure sensor 37 and acquires the stack inlet water temperature T _in from the inlet water temperature sensor 46.

The anode gas circulation flow rate estimation unit 230, the following equation (1), on the basis of the anode gas circulation flow rate Q _a and the anode gas pressure P _a and the stack inlet temperature T _in, the anode gas circulation flow rate at standard conditions Calculate Q _{a_nl} . The anode gas circulation flow rate estimation unit 230 outputs the calculated anode gas circulation flow rate Q a — _nl to the wetting control unit 300 as a measurement value.

  Although the anode gas circulation flow rate is estimated in the present embodiment, a flow rate sensor for detecting the anode gas flow rate may be provided in the anode gas circulation passage 35 and an output signal of the flow rate sensor may be used.

  The wetting control unit 300 configures control means for controlling the wetting state of the electrolyte membrane 111 by operating at least the cathode pressure regulating valve 26 and the anode circulation pump 36 in accordance with the signal output from the membrane wetting state acquisition unit 210. .

  The wetting control unit 300 sets target values of the flow and pressure of the cathode gas and the anode gas based on the target water balance, the stack target current, the flow and pressure of the cathode gas, and the flow and pressure of the anode gas. Calculate each target value of flow rate and pressure.

  When performing the dry operation, the wetting control unit 300 implements the dry operation by the anode gas flow control and the cathode gas pressure control, prior to the dry operation by the cathode gas flow control and the anode gas pressure control. When performing dry operation by anode gas flow rate control and cathode gas pressure control, the wetting control unit 300 reduces the anode gas circulation flow rate according to the size of the target water balance while reducing the cathode gas pressure.

  That is, when the moisture of the electrolyte membrane 111 is reduced based on the signal from the membrane wet state acquisition unit 210, the wetting control unit 300 lowers the cathode gas pressure as compared to the case of increasing the moisture of the electrolyte membrane 111. At the same time, the wetting control unit 300 reduces the anode gas circulation flow rate in accordance with the output signal from the membrane wetting condition acquisition unit 210.

  The wetting control unit 300 outputs an anode target flow rate indicating the target value of the anode gas circulation flow rate and an anode target pressure indicating the target value of the anode gas pressure to the anode gas supply / discharge device command unit 250. Then, the wetting control unit 300 outputs the cathode target flow rate indicating the target value of the cathode gas flow rate and the cathode target pressure indicating the target value of the cathode gas pressure to the cathode gas supply / discharge device command unit 240.

  The cathode gas supply / discharge device command unit 240 controls at least one of the rotational speed of the compressor 22 and the opening degree of the cathode pressure control valve 26 based on the cathode target flow rate and the cathode target pressure.

  In the present embodiment, the cathode gas supply / discharge device command unit 240 controls the rotational speed of the compressor 22 so that the cathode gas flow rate converges to the cathode target flow rate. The cathode gas supply / discharge device command unit 240 also controls the opening degree of the cathode pressure control valve 26 so that the cathode gas pressure converges to the cathode target pressure.

  The anode gas supply / discharge device command unit 250 controls at least one of the rotational speed of the anode circulation pump 36 and the opening degree of the anode pressure control valve 33 based on the anode target flow rate and the anode target pressure.

  In the present embodiment, the anode gas supply / discharge device command unit 250 controls the rotational speed of the anode circulation pump 36 so that the anode gas circulation flow rate converges to the anode target flow rate. Further, the anode gas supply / discharge device command unit 250 controls the opening degree of the anode pressure regulating valve 33 so that the anode gas pressure converges to the anode target pressure.

  FIG. 6 is a view showing an example of the flow rate estimation map set in the anode gas circulation flow rate estimation unit 230. As shown in FIG. Here, the horizontal axis indicates the rotational speed of the anode circulation pump 36, and the vertical axis indicates the anode gas circulation flow rate. As shown in FIG. 6, as the rotational speed of the anode circulation pump 36 increases, the anode gas circulation flow rate increases.

  FIG. 7 is a block diagram showing an example of the detailed configuration of the film wet state acquisition unit 210. As shown in FIG.

  The membrane wet state acquiring unit 210 includes a target HFR calculating unit 211 and a target water balance calculating unit 212.

  The target HFR calculating unit 211 calculates a target HFR for operating the wet state of the electrolyte membrane 111 to a target state according to the operating state of the fuel cell stack 1.

In the present embodiment, a film wetting control map indicating the relationship between the stack output current and the target HFR is recorded in advance in the target HFR calculation unit 211. Upon acquiring the stack output current I _s from the current sensor 51, the target HFR calculating unit 211 refers to the membrane wetting control map and calculates a target HFR related to the acquired stack output current I _s . The membrane wetting control map will be described later with reference to FIG. The target HFR calculator 211 outputs the calculated target HFR to the target water balance calculator 212.

The target HFR calculation unit 211 may calculate the target HFR based on the stack output current I _s using a predetermined calculation formula. Further, the target HFR calculating unit 211 may calculate the target HFR using the required power of the load device 5 instead of the stack output current I _s .

The target water balance calculation unit 212 calculates a target water balance Q _{w — t} for increasing / decreasing the water content of the electrolyte membrane 111 so that the wet state of the electrolyte membrane 111 becomes a target state.

In the present embodiment, the target water balance calculation unit 212 acquires the target HFR from the target HFR calculation unit 211 and acquires the measurement HFR from the impedance measurement device 6. Then, the target water balance calculation unit 212 calculates the target water balance Q _{w — t} so that the deviation between the measured HFR and the target HFR converges to zero.

For example, the target water balance calculation unit 212 subtracts the target HFR from the measured HFR to obtain a deviation between the measured HFR and the target HFR, and executes PI control based on the deviation to calculate the target water balance Q _{w — t} . The target water balance calculation unit 212 outputs the calculated target water balance Q _{w — t} to the wetting control unit 300.

  FIG. 8 is a conceptual diagram showing an example of the membrane wetting control map set in the target HFR computing unit 211. As shown in FIG. Here, the horizontal axis indicates the stack output current, and the vertical axis indicates the target HFR. As the target HFR becomes larger, the electrolyte membrane 111 becomes easier to dry, and as the target HFR becomes smaller, the electrolyte membrane 111 becomes easier to become wet.

  The target HFR is set so that liquid water generated with the power generation of the fuel cell stack 1 is retained in the cathode gas flow path 131 and the flow of cathode gas is not obstructed due to the retained liquid water .

In the membrane wetting control map, when the stack output current is in a large current range larger than the predetermined current value I ₁ , the cathode gas flow rate becomes sufficiently large, so the influence of liquid water remaining in the fuel cell stack 1 It becomes smaller. Therefore, the target HFR in the large current range is smaller than the target HFR in the small current range and set to a constant value.

On the other hand, when the stack output current is in a small current range from zero to the current value I ₁ , the target HFR increases as the stack output current decreases.

  The reason for this setting is that as the cathode gas flow rate decreases, the flow of the cathode gas tends to be blocked by the liquid water remaining in the cathode gas flow path 131. Therefore, the target HFR in the small current range is set higher than the target HFR in the large current range.

  FIG. 9 is a time chart showing an example of the drying operation performed by the wetting control unit 300.

  FIG. 9A shows a change in water balance in the fuel cell stack 1. The water balance is a balance between the amount of water generated along with the power generation of the fuel cell stack 1 and the amount of water discharged from the fuel cell stack 1 to the outside of the fuel cell system 100. FIG. 9 (B) is a view showing the change of the cathode gas pressure. FIG. 9C is a view showing a change of the anode gas circulation flow rate. FIG. 9D is a view showing a change in the amount of anode circulating water. The anode circulating water amount is the total amount of water held in the anode gas flow passage 121 and the anode gas circulation passage 35. The horizontal axis of each drawing from FIG. 9 (A) to FIG. 9 (D) is a common time axis.

  In each drawing of FIG. 9, the dry operation when executing the anode gas weight reduction control after executing the cathode gas pressure reduction control is indicated by a solid line, and the cathode gas pressure reduction control is performed after performing the anode gas weight reduction control. The dry operation when done is shown by a dotted line.

  At time t0, as shown in FIG. 9A, the target water balance, which is the target value of the water balance of the fuel cell stack 1, drops significantly, and the dry operation is performed. For example, when the accelerator pedal is depressed and the required power of the load device 5 is significantly increased, the electrolyte membrane 111 is humidified by a large amount of water generated by the fuel cell stack 1 generation, and thereafter the required power of the load device 5 decreases. When the target water balance falls significantly.

  In the present embodiment, as indicated by the solid line in FIG. 9B, the opening degree of the cathode pressure regulating valve 26 is gradually lowered to lower the cathode gas pressure. Along with this, the partial pressure of water vapor in the cathode gas flow channel 131 decreases, and the amount of water vapor from the cathode gas flow channel 131 to the anode gas flow channel 121 decreases, as shown by the solid line in FIG. , Anode circulation water amount decreases. Thus, as shown by the solid line in FIG. 9A, the water balance of the fuel cell stack 1 is reduced. That is, the water content of the electrolyte membrane 111 is reduced.

  At time t1, the cathode gas pressure reaches the lower limit value of the dry operation, and as shown by the solid line in FIG. 9C, the rotational speed of the anode circulation pump 36 is decreased to decrease the anode gas circulation flow rate. Along with this, as shown by the solid line in FIG. 9 (D), the amount of anode circulating water decreases. Thus, as shown by the solid line in FIG. 9A, the water balance of the fuel cell stack 1 is reduced.

  At time t2, the water balance of the fuel cell stack 1 reaches the target value, and the dry operation ends.

  On the other hand, as shown by the dotted line in FIG. 9C, when the decrease control of the anode gas is executed prior to the step-down control of the cathode gas at time t0, as shown by the dotted line in FIG. Since the amount of water does not decrease, the water balance of the fuel cell stack 1 also does not decrease as shown by the dotted line in FIG.

  At this time, as shown by the dotted line in FIG. 9 (B), the cathode gas pressure is maintained constant in a high state. Since the power consumption of the compressor 22 becomes higher as the cathode gas pressure becomes higher, the power consumption of the compressor 22 is unnecessarily kept high during the period from time t0 to time t1. Furthermore, as indicated by the broken line in FIG. 9A, the water balance of the fuel cell stack 1 does not reach the target value at time t2, and therefore the time required for the dry operation becomes long.

  On the other hand, the wetting control unit 300 of the present embodiment executes the step-down control to lower the cathode gas pressure in preference to the reduction control to reduce the anode gas circulation flow rate, so the power consumption of the compressor 22 is reduced. While, the dry operation can be completed early.

  According to the first embodiment of the present invention, the fuel cell system 100 faces the flow of the cathode gas supply / discharge device (oxidant system) 2 through which the cathode gas containing the oxidant flows and the flow of the cathode gas supply / discharge device 2 The anode gas containing fuel flows to the anode gas supply / discharge device (fuel system) 3. The cathode gas supply / discharge device (oxidizer system) 2 includes a cathode pressure regulating valve (oxidizer system pressure adjusting means) 26 for adjusting the pressure of the fuel cell stack 1, and the cathode gas supplied from the compressor 22 to the fuel cell stack 1 As a result, a drainage means for draining the water generated in the electrolyte membrane 111 is configured. The anode gas supply / discharge device 3 includes an anode gas circulation passage 35 and an anode circulation pump (actuator) 36 that constitute a fuel circulation means for circulating anode gas containing fuel discharged from the fuel cell stack 1. The generated water is reserved in the anode gas circulation passage 35.

  The controller (wet control apparatus) 200 that controls the fuel cell system 100 includes a membrane wet state acquisition unit (acquisition means) 210 that acquires a signal indicating the wet state of the electrolyte membrane 111 as a wet state signal. Furthermore, the controller 200 includes a wetting control unit (control means) 300 that controls the wet state of the electrolyte membrane 111 by operating at least the anode circulation pump 36 and the cathode pressure regulating valve 26 based on the wet state signal. The wetting control unit 300 controls the cathode pressure regulating valve 26 prior to the anode circulation pump 36 at the time of a dry operation to reduce the water content of at least the electrolyte membrane 111.

  Thus, when the dry operation is performed, the operation of the anode circulation pump 36 is suppressed as compared with the operation of the cathode pressure regulating valve 26, so the cathode pressure regulating valve 26 can be operated earlier. For this reason, as in the dry operation 2 shown in FIG. 4, the start of the dry operation in a situation where the water content of the electrolyte membrane 111 is difficult to reduce even if the anode circulation pump 36 is controlled or the water content increases. And the cathode pressure regulating valve 26 can be driven with priority. As described above, wasteful control of the anode circulation pump 36 is suppressed at least in the dry operation, so that unnecessary waiting time as shown by the dotted line in FIG. 9B can be reduced. Therefore, the wet state of the fuel cell stack 1 can be efficiently controlled.

  Further, according to the present embodiment, as shown in FIG. 2, in the fuel cell 10, the cathode gas flow path 131 for passing the cathode gas to one side of the electrolyte membrane 111 and the other side of the electrolyte membrane 111. On the other hand, an anode gas flow passage 121 for passing the anode gas in a direction opposite to the direction of the cathode gas flowing to the cathode gas flow passage 131 is formed. By changing the opening degree of the cathode pressure control valve 26, the pressure of the cathode gas supplied to the cathode gas flow path 131 is increased or decreased. Then, as shown in FIGS. 9B and 9D, the wetting control unit 300 reduces the amount of anode circulating water, which is the amount of water circulating through the anode gas flow channel 121, at least at the time of the dry operation. The pressure of the cathode gas flow path 131 is lowered.

  As a result, by performing the step-down control of the cathode gas when performing the dry operation, it is possible to lower the torque of the compressor 22, and the power consumption of the compressor 22 in the dry operation can be reduced early. Therefore, the fuel consumption of the dry operation can be improved.

  Further, according to the present embodiment, the anode gas circulation passage 35 is a passage for introducing the anode gas discharged from one end of the anode gas passage 121 to the other end of the anode gas passage 121 and circulating the same. By changing the rotational speed of the anode circulation pump 36 provided in the anode gas circulation passage 35, the circulation flow rate of the anode gas flowing through the anode gas circulation passage 35 is increased or decreased. Then, as shown in FIG. 9C and FIG. 9D, the wetting control unit 300 reduces the circulation flow rate of the anode gas when reducing the amount of anode circulation water at least at the time of the dry operation.

  As a result, when the dry operation is performed, the rotational speed of the anode circulation pump 36 is reduced, so that the power consumption of the anode circulation pump 36 can be reduced. Therefore, power consumption of the compressor 22 and the anode circulation pump 36 can be reduced.

  In addition to this, anode gas reduction control is performed during or after execution of cathode gas pressure reduction control. As shown in FIG. 4, since the anode gas weight loss control is performed after the cathode gas pressure is reduced and the degree of contribution to the dry operation can be obtained, the dry operation is performed more effectively. can do.

  Therefore, the dry operation can be effectively performed, and the power consumption of the fuel cell system 100 can be reduced. That is, it is possible to achieve both the reduction of the time required for the dry operation and the improvement of the fuel efficiency of the fuel cell system 100.

  As described above, according to the present embodiment, the dry operation can be completed early and effectively, so that the wet state of the electrolyte membrane 111 can be efficiently controlled.

Second Embodiment
Next, a configuration example of the wetting control unit 300 when performing the dry operation will be described in detail.

  FIG. 10 is a block diagram showing an example of a detailed configuration of the wetting control unit 300 according to the second embodiment of the present invention. Here, the configuration of the wetting control unit 300 when performing the dry operation is shown.

  The wetting control unit 300 includes a DRY operation priority setting unit (hereinafter simply referred to as a "priority setting unit") 310, a cathode target pressure calculation unit 320, an anode target flow rate calculation unit 330, and a cathode target flow rate calculation unit 340. And an anode target pressure calculator 350.

  The priority setting unit 310 sets the priority of control processing for controlling the respective state quantities of the anode gas and the cathode gas used for the wet control in accordance with the wet state of the fuel cell stack 1.

  In the present embodiment, the priority setting unit 310 sets priorities for each control of anode gas flow control, anode gas pressure control, cathode gas flow control, and cathode gas pressure control based on the measured HFR from the impedance measurement device 6. Set That is, the priority setting unit 310 adjusts the load ratio of each operation of the anode circulation pump 36, the anode pressure regulation valve 33, the compressor 22, and the cathode pressure regulation valve 26 according to the wet state of the electrolyte membrane 111.

  First, based on the measured HFR and the target HFR of the fuel cell stack 1, the priority setting unit 310 determines whether it is necessary to perform the dry operation or to perform the wet operation. In the present embodiment, when the measurement HFR is equal to or higher than the target HFR, the priority setting unit 310 determines that the wet operation needs to be performed, and outputs the wet operation parameter. When the measured HFR is lower than the target HFR, the priority setting unit 310 determines that the dry operation needs to be performed, and outputs a dry operation parameter for setting the priority related to each control.

  When the measured HFR of the fuel cell stack 1 is equal to or higher than the target HFR, the priority setting unit 310 outputs measured values of the cathode gas flow rate, the cathode gas flow rate, and the anode gas pressure as wet operation parameters.

  On the other hand, when the measurement HFR is lower than the target HFR, the priority setting unit 310 outputs the wet operation value when the electrolyte film 111 is in the wet state, as the dry operation parameter, instead of each measured value. .

  For example, a value smaller than the measured value of the cathode gas flow rate is used as the WET operation value of the cathode gas flow rate control, and a value larger than the measured value of the anode gas flow rate is used as the WET operation value of the anode gas flow rate control Be Further, as the WET operation value of the anode gas pressure control, a value smaller than the measurement value of the anode gas pressure is used.

  In the present embodiment, the priority setting unit 310 outputs the cathode lower limit flow rate, the anode upper limit flow rate, and the anode lower limit pressure as dry operation parameters. These dry operation parameters are the wet operation values used when transitioning the electrolyte membrane 111 to the most wet state.

  The cathode lower limit flow rate is a lower limit value of the cathode gas flow rate determined so that flooding does not occur in the fuel cell stack 1. The flooding refers to a state in which liquid water associated with power generation is clogged with the electrolyte membrane 111 and power generation of the fuel cell stack 1 becomes unstable. That is, the cathode lower limit flow rate is set to the smallest flow rate as long as the power generation performance of the fuel cell stack 1 can be secured. The cathode lower limit flow rate is preset using experimental data, simulation results, and the like.

  The anode upper limit flow rate is the upper limit value of the anode gas circulation flow rate determined by the operation characteristics of the anode circulation pump 36. Specifically, the anode upper limit flow rate corresponds to the PQ characteristic of the anode circulation pump 36, the pressure loss of the anode gas circulation system, and the anode gas flow rate when the rotational speed of the anode circulation pump 36 reaches the upper limit value. Set based on. That is, the anode upper limit flow rate is set to the largest flow rate as long as the power generation performance of the fuel cell stack 1 can be secured.

  The anode lower limit pressure is a lower limit value of the anode gas pressure determined according to the operating state of the fuel cell stack 1. For example, the anode lower limit pressure is the lower limit value of the anode gas pressure calculated based on the required power of the load device 5, or the lower limit value of the anode gas pressure set based on the allowable pressure of the electrolyte membrane 111 and the cathode gas pressure. It is set to the largest value among such as. That is, the anode lower limit pressure is set to the lowest pressure as long as the power generation performance of the fuel cell stack 1 can be secured.

  Although the priority setting unit 310 according to the present embodiment determines whether the wet control is the dry operation or the wet operation based on the measured HFR, the dry operation is performed when the target water balance is larger than a predetermined threshold. May be determined to be implemented. Alternatively, the priority setting unit 310 may acquire the target water balance at a predetermined sampling cycle, and determine that the dry operation is started when the current value of the target water balance is smaller than the previous value. .

  The cathode target pressure calculation unit 320 configures a pressure control unit that controls the cathode gas pressure based on the wettability of the electrolyte membrane 111 and the anode gas circulation flow rate.

  In the present embodiment, the cathode target pressure calculation unit 320 calculates the cathode target pressure based on the target water balance, the cathode gas flow rate, the anode gas flow rate, and the anode gas pressure, which are correlated with the wettability of the electrolyte membrane 111. Calculate The cathode target pressure calculator 320 outputs the calculated cathode target pressure to the cathode gas supply / discharge device commander 240.

  The cathode target pressure calculation unit 320 increases the cathode target pressure such that the water content of the electrolyte membrane 111 increases as the target water balance increases. On the other hand, the cathode target pressure calculation unit 320 reduces the cathode target pressure so that the water content of the electrolyte membrane 111 decreases as the target water balance decreases.

  In the dry operation, the cathode target pressure calculation unit 320 increases the amount of anode circulation water and increases the water content of the electrolyte membrane 111 as the anode gas circulation flow rate increases or as the anode gas pressure decreases, so the cathode target pressure Make it smaller. Further, as the cathode gas pressure decreases, the amount of drainage carried out of the fuel cell stack 1 by the cathode gas decreases and the water content of the electrolyte membrane 111 increases, so the cathode target pressure calculation unit 320 decreases the cathode target pressure.

  In the present embodiment, the cathode target pressure calculation unit 320 acquires, from the priority setting unit 310, the anode upper limit flow rate, the anode lower limit pressure, and the cathode lower limit flow rate as the WET operation value. For this reason, the cathode target pressure calculation unit 320 can reduce the cathode target pressure as compared with the case of acquiring each measurement value of the anode gas flow rate, the anode gas pressure, and the cathode gas flow rate. Thus, in the dry operation, the priority setting unit 310 can set the priority of cathode pressure control higher than the priority of anode gas flow control, anode gas pressure control, and cathode gas flow control.

  The anode target flow rate calculation unit 330 configures a flow rate control unit that controls the anode gas flow rate based on the degree of wettability of the electrolyte membrane 111 and the cathode gas pressure supplied to the fuel cell 10.

  In the present embodiment, the anode target flow rate calculation unit 330 calculates the anode target flow rate based on the target water balance, the cathode gas flow rate, the cathode gas pressure, and the anode gas pressure. The anode target flow rate calculation unit 330 outputs the calculated anode target flow rate to the anode gas supply / discharge device command unit 250.

  The anode target flow rate calculation unit 330 increases the anode target flow rate such that the water content of the electrolyte membrane 111 increases as the target water balance increases. On the other hand, the anode target flow rate calculation unit 330 reduces the anode target flow rate so that the water content of the electrolyte membrane 111 decreases as the target water balance decreases.

  In the dry operation, as the cathode gas flow rate decreases or as the cathode gas pressure increases, the anode target flow rate calculation unit 330 reduces the amount of drained water taken out of the fuel cell stack 1 by the cathode gas, thereby reducing the anode target flow rate. Further, the anode target flow rate calculation unit 330 reduces the anode target flow rate because the amount of water flowing from the cathode gas flow path 131 into the anode gas flow path 121 increases and the amount of anode circulating water increases as the anode gas pressure decreases. .

  In the present embodiment, the anode target flow rate calculation unit 330 acquires the cathode lower limit flow rate and the anode lower limit pressure from the priority setting unit 310 as the wet operation value, and acquires the measured value of the cathode gas pressure from the cathode pressure sensor 24. . For this reason, the anode target flow rate calculation unit 330 can reduce the anode target flow rate as compared to the case where measurement values of the cathode gas flow rate and the anode gas pressure are acquired. Thus, in the dry operation, the priority setting unit 310 can set the priority of the anode flow control higher than the priority of the cathode gas flow control and the anode gas pressure control.

  The cathode target flow rate calculation unit 340 reduces the cathode target flow rate so that the water content of the electrolyte membrane 111 increases as the target water balance increases. On the other hand, the cathode target flow rate calculation unit 340 increases the cathode target flow rate such that the water content of the electrolyte membrane 111 decreases as the target water balance decreases.

  In the dry operation, the cathode target flow rate calculating unit 340 increases the cathode target flow rate because the amount of drainage carried out of the fuel cell stack 1 by the cathode gas decreases as the cathode gas pressure increases. In the cathode target flow rate calculation unit 340, the amount of water flowing from the cathode gas flow path 131 into the anode gas flow path 121 increases and the amount of anode circulation water increases as the anode gas flow rate increases or as the anode gas pressure decreases. Therefore, the cathode target flow rate is increased.

  In the present embodiment, the cathode target flow rate calculation unit 340 acquires the anode lower limit pressure from the priority setting unit 310 as the wet operation value. Then, the cathode target flow rate calculation unit 340 acquires an estimated value of the anode gas circulation flow rate from the anode gas circulation flow rate estimation unit 230, and acquires a measured value of the cathode gas pressure from the cathode pressure sensor 24. For this reason, the cathode target flow rate calculation unit 340 can increase the cathode target flow rate as compared to the case where the measurement value of the anode gas pressure is acquired. Thus, the priority setting unit 310 can set the priority of cathode gas flow control higher than the priority of anode gas pressure control in the dry operation.

  The anode target pressure calculator 350 calculates the anode target pressure based on the target water balance, the cathode gas flow rate, the cathode gas pressure, and the anode gas flow rate. The anode target pressure calculation unit 350 outputs the calculated anode target pressure to the anode gas supply / discharge device command unit 250.

  The anode target pressure calculation unit 350 reduces the anode target pressure so that the water content of the electrolyte membrane 111 increases as the target water balance increases. On the other hand, the anode target pressure calculation unit 350 increases the anode target pressure so that the water content of the electrolyte membrane 111 decreases as the target water balance decreases.

  In the dry operation, as the cathode gas pressure decreases or the cathode gas pressure increases, the anode target pressure calculation unit 350 increases the anode target pressure because the amount of water discharged from the fuel cell stack 1 by the cathode gas decreases. Do. Further, the anode target pressure calculation unit 350 increases the anode target pressure because the anode circulating water amount increases as the anode gas flow rate increases.

  In the present embodiment, the anode target pressure calculation unit 350 obtains the measured values of the cathode gas flow rate and the cathode gas pressure from the flow rate sensor 23 and the cathode pressure sensor 24 respectively, and measures the measured values from the anode gas circulation flow rate estimation unit 230. Obtain the anode gas circulation flow rate. For this reason, the anode target pressure calculation unit 350 can appropriately increase or decrease the anode target pressure according to the measured values of the cathode gas flow rate, the cathode gas pressure, and the anode gas flow rate.

  As described above, in the dry operation, the priority setting unit 310 sets the priority in the order of cathode gas pressure control, anode gas flow control, cathode gas flow control, and anode gas pressure control. As a result, since the cathode gas pressure control is executed prior to the anode gas flow rate control, power consumption of the compressor 22 can be reduced as shown in FIG. Time can be shortened.

  When the cathode gas flow rate control is performed in the dry operation, the power consumption of the compressor 22 is increased to increase the rotational speed of the compressor 22. As described above, in the present embodiment, since the anode gas flow rate control is performed prior to the cathode gas flow rate control, it is possible to suppress an increase in the power consumption of the compressor 22.

  Further, when the anode circulation pump 36 does not operate due to an abnormality of the anode circulation pump 36 or the like, the weight reduction control for reducing the anode gas circulation flow rate can not be performed. In such a case, the priority setting unit 310 outputs the measured value of the anode gas flow rate instead of the anode upper limit flow rate. That is, when the anode circulation pump 36 does not operate during the dry operation, the wetting control unit 300 causes the anode gas flow rate set in the cathode target pressure calculation unit 320 to wet the electrolyte membrane 111 higher than the present. Switch to the measured value or estimated value of the anode gas circulation flow rate at the time of

  As described above, when the anode gas flow rate can not be controlled, the cathode target pressure calculation unit 320 calculates the cathode target pressure using the actual anode gas flow rate supplied to the fuel cell stack 1, so that the anode flow rate control is performed. It is possible to execute the dry operation suitable for the abnormal state of the system. When the anode gas flow rate control can not be performed, the calculation in the priority setting unit 310 may be stopped.

  FIG. 11 is a block diagram showing an example of a detailed configuration of the cathode target pressure calculation unit 320 when performing the dry operation.

  The cathode target pressure calculation unit 320 includes a saturated water vapor pressure calculation unit 321, a generated water generation amount calculation unit 322, and a target drainage amount calculation unit 323. Further, the cathode target pressure calculation unit 320 includes an An / Ca flow ratio calculation unit 324, a cathode relative humidity calculation unit 325, a cathode wetting required pressure calculation unit 326, a cathode lower limit pressure calculation unit 327, and a cathode target pressure setting unit 328. And.

The saturated water vapor pressure calculation unit 321 calculates the saturated water vapor pressure P _sat in the fuel cell stack 1. In the present embodiment, the saturated vapor pressure calculating unit 321, the inlet water temperature sensor 46 and the outlet water temperature sensor 47, respectively, to get the stack inlet temperature T _in and the stack outlet temperature T _out, these average values, the fuel cell stack Calculated as a temperature T of 1. Then, the saturated water vapor pressure calculation unit 321 calculates the saturated water vapor pressure P _sat based on the temperature T of the fuel cell stack 1 as in the following formula (2).

As shown in the equation (2), as the stack temperature T becomes higher, the saturated water vapor pressure P _sat becomes higher. The saturated water vapor pressure calculating unit 321 outputs the calculated saturated water vapor pressure P _sat to the cathode wetting required pressure calculating unit 326.

  Based on the output current of the fuel cell stack 1, the power generation water quantity calculation unit 322 calculates a power generation water quantity that indicates the total amount of water generated with the power generation of each fuel cell 10.

In the present embodiment, the electrical generation product water amount calculating unit 322 obtains the stack output current I _s from the current sensor 51, as in the following equation (3), based on the stack output current I _s, the power generation amount of water Q _{W_in} calculate.

  Here, N is the number of fuel cells 10 stacked on the fuel cell stack 1, and F [C / mol] is a Faraday constant (= 96485.39). Further, “60” is a conversion value for converting the amount of power generation water per unit time from second unit [sec] to minute unit [min]. “22.4” is a volume of 1 mole [mol] of the ideal gas in the standard state.

The generated water generation amount calculating unit 322 outputs the calculated generated water generation amount _{Qw_in} to the target drainage amount calculating unit 323.

The target drainage amount calculation unit 323 calculates the target drainage amount _{Qw_out} indicating the water to be discharged from the fuel cell stack 1 by calculating the difference between the generated water amount _{Qw_in} and the target water balance _{Qw_t} . In the present embodiment, the target water discharge amount calculation unit 323, as in the following equation (4), by subtracting the target water balance Q _{W_t} from the generator water quantity Q _{W_in} calculates a target amount of waste water _Q w_out.

The target drainage amount calculation unit 323 outputs the calculated target drainage amount Q _{w_out} to the An / Ca flow rate ratio calculation unit 324. At the same time, the target drainage amount calculation unit 323 outputs the target drainage amount _{Qw_out} to the anode target flow rate calculation unit 330, the cathode target flow rate calculation unit 340, and the anode target pressure calculation unit 350.

The An / Ca flow ratio calculating unit 324 determines An / Ca flow ratio _{Kac_max} , which indicates the ratio of the anode gas flow rate to the cathode gas flow rate in the fuel cell stack 1, in order to obtain the amount of water circulating inside the fuel cell stack 1. Calculate

In this embodiment, An / Ca flow ratio calculating section 324, a priority setting unit 310 acquires the anode upper flow Q _{a_max} and cathode lower flow rate _Q c_min. The An / Ca flow rate ratio calculation unit 324 calculates the An / Ca flow rate ratio _{Kac_max} as in the following equation (5).

In general, the An / Ca flow ratio changes in accordance with the inter-electrode differential pressure which is the differential pressure between the anode gas pressure and the anode gas pressure. Therefore, the An / Ca flow rate ratio calculating unit 324 corrects the An / Ca flow rate ratio _{Kac_max} according to the inter-electrode differential pressure.

  In the present embodiment, a flow ratio correction map indicating the relationship between the anode gas pressure and the inter-electrode differential pressure of the anode gas pressure and the correction coefficient of the An / Ca flow ratio is recorded in advance in the An / Ca flow ratio calculation unit 324. The flow rate ratio correction map will be described later with reference to FIG.

The An / Ca flow rate ratio calculation unit 324 acquires the anode lower limit pressure _{Pa_min} from the priority setting unit 310, and acquires the measured value _{Pc_sens} of the cathode gas pressure from the cathode pressure sensor 24. Then, the An / Ca flow rate ratio calculation unit 324 subtracts the cathode gas pressure P _{c — sens} from the anode lower limit pressure P a — _min to calculate the inter-electrode differential pressure ΔP _{ac — cs} .

After calculating the inter-electrode differential pressure _{ΔPac_cs} , the An / Ca flow ratio calculating unit 324 refers to the flow ratio correction map and calculates a correction coefficient _{Eac_min} related to the calculated inter-electrode differential pressure _{ΔPac_cs} . An / Ca flow ratio calculating section 324, the following equation (6), on the basis of the calculated correction coefficient E _{Ac_min,} the An / Ca flow ratio K _{ac_min,} An when interelectrode differential pressure [Delta] P _ac is zero / Ca flow rate ratio is corrected to _{ac_min_0} .

The An / Ca flow rate ratio calculating unit 324 outputs the corrected An / Ca flow rate ratio _{Kac_max_0} to the cathode relative humidity calculating unit 325.

The cathode relative humidity calculation unit 325 calculates the cathode outlet relative humidity _{RHc_out_min} based on the corrected An / Ca flow ratio _{Kac_max_0} . The cathode outlet relative humidity _{RHc_out_min} is a value obtained by dividing the cathode gas humidity on the outlet (downstream) side of the cathode gas flow channel 131 by the anode gas humidity on the inlet (upstream) side of the anode gas flow channel 121.

The cathode relative humidity calculating section 325, the relative humidity / flow ratio map interelectrode differential pressure [Delta] P _ac shows the relationship between An / Ca flow ratio and the cathode outlet relative humidity at zero is recorded in advance. The relative humidity / flow rate ratio map will be described later with reference to FIG.

Cathode relative humidity calculation unit 325 obtains the post-correction An / Ca flow ratio K _{Ac_max_0,} with reference to the relative humidity / flow ratio map, a cathode outlet relative humidity RH _{C_out_min} associated with An / Ca flow ratio K _{Ac_max_0} calculate.

The cathode relative humidity calculation unit 325 outputs the calculated cathode outlet relative humidity _{RHc_out_min} to the cathode wetting required pressure calculation unit 326.

The cathode wetting required pressure calculation unit 326 computes the cathode wetting required pressure P _{c — rw} for targeting the wet state of the fuel cell stack 1 based on the target displacement Q _{w_out} and the cathode outlet relative humidity RH _{c_out_min.} Do.

In the dry operation, the cathode wetting required pressure calculation unit 326 acquires the cathode lower limit flow rate _{Qc_min} from the priority setting unit 310 and acquires the saturated water vapor pressure P _sat from the saturated water vapor pressure calculation unit 321. Then, the cathode wetting required pressure calculation unit 326 performs cathode wetting based on the cathode lower limit flow rate _{Qc_min} , the saturated water vapor pressure P _sat , the target drainage amount Q _{w_out} and the cathode outlet relative humidity RH _{c_out_min} as in the following equation (7). The required pressure P _{c — rw} is calculated.

As shown in the equation (7), as the cathode lower limit flow rate _{Qc_min} decreases, the anode wetting required pressure _{Pa_rw} decreases. Therefore, the cathode wetting requirement pressure _{Pc_rw} can be lowered by using the cathode lower limit flow rate _{Qc_min} instead of the measurement value of the cathode gas flow rate.

The cathode wetting required pressure calculation unit 326 outputs the calculated anode wetting required pressure P a — _rw to the cathode target pressure setting unit 328.

  The cathode lower limit pressure calculator 327 calculates the cathode lower limit pressure according to the operating state of the fuel cell system 100. The cathode lower limit pressure is a lower limit value of the cathode gas pressure set by a requirement different from the wetting requirement of the electrolyte membrane 111. The demand different from the demand for wetting of the electrolyte membrane 111 includes, for example, a demand for power generation of the load device 5, a demand for protection of the electrolyte membrane 111, a demand for flood prevention, and the like.

  For example, the cathode lower limit pressure calculation unit 327 obtains the anode gas pressure from the anode pressure sensor 37, and subtracts the allowable pressure of the electrolyte membrane 111 determined in advance from the anode gas pressure to obtain the cathode film protection required pressure. calculate. Further, the cathode lower limit pressure calculation unit 327 calculates the cathode load required pressure based on the required power of the load device 5.

The cathode lower limit pressure calculation unit 327 outputs the calculated cathode load required pressure, cathode film protection required pressure, and the like as the cathode lower limit pressure to the cathode target pressure setting unit 328. The cathode target pressure setting unit 328 The larger one of the required pressure P _{c — rw} is output as a cathode target pressure to the cathode gas supply / discharge device command unit 240.

FIG. 12 is a conceptual diagram showing an example of a flow rate ratio correction map set in the An / Ca flow rate ratio calculation unit 324. Here, the horizontal axis is the inter-electrode differential pressure ΔP _ac (= P _a −P _c ) obtained by subtracting the cathode gas pressure P _c from the anode gas pressure P _a , and the vertical axis corrects the An / Ca flow ratio. The correction factor E _ac is

The correction coefficient E _ac is normalized so as to be “1” when the inter-electrode differential pressure ΔP _ac is “0”. The flow ratio correction map is preset based on experimental data etc. when the cathode gas pressure and the anode gas pressure are mutually changed.

In the flow rate ratio correction map, as the inter-electrode differential pressure ΔP _ac becomes larger than zero, the flow rate of the anode gas leaking from the anode gas flow path 121 to the cathode gas flow path 131 increases, so the correction coefficient E _ac is “1”. It becomes bigger than. On the other hand, as the inter-electrode differential pressure ΔP _ac becomes smaller than zero, the flow rate of the cathode gas leaking from the cathode gas flow path 131 to the anode gas flow path 121 increases, so the correction coefficient E _ac becomes smaller than “1”. .

Thus, in the fuel cell stack 1, in accordance with the inter-electrode differential pressure [Delta] P _ac, since the cathode gas flow rate of An / Ca flow ratio K _ac for anode gas flow rate changes, by using the correction coefficient E _ac An / Ca The flow rate ratio _Kac is corrected.

FIG. 13 is a conceptual diagram showing an example of a relative humidity / flow rate ratio map set in the cathode relative humidity calculation unit 325. As shown in FIG. Here, the horizontal axis represents An / Ca flow rate ratio _Kac indicating the ratio of the anode gas flow rate to the cathode gas flow rate, and the vertical axis represents the cathode outlet relative humidity indicating the cathode gas relative humidity at the outlet of the cathode gas flow path 131 It is RH _{c_out} .

The cathode outlet relative humidity _{RHc_out} has a very low anode gas flow rate, and a state in which almost all of the generated water associated with power generation is discharged from the cathode gas flow path 131 is “100%”. The relative humidity / flow rate ratio map is preset using experimental data etc. when the cathode gas flow rate and the anode gas flow rate are mutually changed. For example, the relative humidity / flow rate ratio map is set by the stack temperature, an average value when the hydrogen concentration or the like is changed, or a statistical value which is arithmetically processed to reduce an error.

The relative humidity / flow ratio map, inter-electrode differential pressure [Delta] P _ac characteristics of An / Ca flow ratio K _{Ac_0} when zero is recorded. Here is shown An / Ca flow ratio K _{Ac_0} is by solid lines, and An / Ca flow ratio when interelectrode differential pressure [Delta] P _ac is greater than zero in order to facilitate understanding, inter-electrode differential pressure [Delta] P _ac is The An / Ca flow ratio when smaller than zero is indicated by the dashed line. The characteristics of the An / Ca flow rate ratio indicated by the broken line can be obtained by multiplying the correction coefficient of the flow rate ratio correction map shown in FIG. 12 by the An / Ca flow rate ratio _{Kac_0} .

The relative humidity / flow ratio map, as An / Ca flow ratio K _ac is reduced, since the amount of waste water which is taken out from the fuel cell stack 1 by the cathode gas is increased, the cathode outlet relative humidity RH _{c_out} increases. Further, as the inter-electrode differential pressure ΔP _ac increases, the flow rate of water vapor flowing from the cathode gas flow path 131 into the anode gas flow path 121 decreases, so the cathode outlet relative humidity _{RHc_out} increases.

As described above, in the cathode target pressure calculation unit 320, in _order to quickly reduce the cathode wetting required pressure P _{c — r w} when performing the dry operation, the cathode outlet relative humidity RH _{c — out} is reduced from the relationship of equation (7). At the same time, it is necessary to reduce the cathode gas flow rate.

In _order to reduce the cathode outlet relative humidity _{RHc_out} , the An / Ca flow rate ratio _{Kac_0} may be increased from the relationship of the relative humidity / flow rate ratio map shown in FIG. An, / Ca To increase flow ratio K _{Ac_0} is the cathode gas flow rate is reduced, the anode gas flow with increasing anode as the correction coefficient E _ac from flow ratio correction map of the relationship shown in FIG. 12 becomes smaller The gas pressure may be reduced.

In the present embodiment, the priority setting unit 310 _changes the cathode lower limit flow rate _{Qc_min} , the anode upper limit flow rate _{Qa_max} and the anode lower limit pressure _{Pa_min} as measurement values in the dry operation as the _wet operation value, and the cathode target pressure calculation unit 320 Output to As a result, the An / Ca flow rate ratio _{Kac_max} in the equation (5) is larger than in the case where measured values of the cathode gas flow rate and the anode gas flow rate are used, so the An / Ca flow rate ratio K in the equation (6) _{ac_max_0} can be increased. Furthermore, by using the anode lower limit pressure P a — _min , the correction coefficient E _{ac — min} of the An / Ca flow rate ratio becomes smaller, so the An / Ca flow rate ratio K _{ac — max — 0} can be further increased.

For this reason, An / Ca flow rate ratio _{Kac_max_0} becomes the largest, and cathode outlet relative humidity _{RHc_out_min} becomes the smallest. Therefore, since the priority of cathode gas pressure control in the dry operation is the highest, the cathode wetting required pressure P _{c — rw} can be lowered early.

  FIG. 14 is a block diagram showing an example of a functional configuration of the anode target flow rate calculation unit 330 when performing a dry operation.

  The anode target flow rate calculation unit 330 includes a cathode relative humidity calculation unit 331, an / Ca flow rate ratio calculation unit 332, an anode wetting required flow rate calculation unit 333, an anode lower limit flow rate calculation unit 334, and an anode target flow rate setting unit 335 including.

The cathode relative humidity calculation unit 331 calculates a target cathode outlet relative humidity _{RHc_out_ps} based on the target displacement amount _{Qw_out} from the target displacement amount calculation unit 323.

In the present embodiment, the cathode relative humidity calculation unit 331 acquires the cathode lower limit flow rate _{Qc_min} from the priority setting unit 310, acquires the cathode gas pressure _{Pc_sens} from the cathode pressure sensor 24, and saturates from the saturated water vapor pressure calculation unit 321. Obtain the water vapor pressure P _sat .

The cathode relative humidity calculating section 331, as shown in the following equation (8), on the basis of the cathode lower flow rate Q _{C_min} and the cathode gas pressure P _{C_sens} and saturated water vapor pressure P _sat and the target wastewater Q _{W_out,} cathode outlet relative humidity Calculate RH _{c_out_ps} .

The cathode relative humidity calculating unit 331 outputs the calculated cathode outlet relative humidity RH _{c_out_ps} to the An / Ca flow ratio calculating unit 332.

An / Ca flow ratio calculation unit 332, based on the cathode outlet relative humidity RH _{C_out_ps,} interelectrode differential pressure [Delta] P _ac is calculates An / Ca flow ratio K _{Ac_ps_0} when zero.

An In this embodiment, An / Ca flow ratio calculating unit 332 acquires the cathode outlet relative humidity RH _{C_out_ps,} which refers to the relative humidity / flow ratio map of FIG. 13, associated with the cathode outlet relative humidity RH _{C_out_ps} / Ca flow rate ratio _{Kac_ps_0} is calculated.

Also, the An / Ca flow rate ratio calculation unit 332 acquires the anode lower limit pressure _{Pa_min} from the priority setting unit 310, and acquires the cathode gas pressure _{Pc_sens} from the cathode pressure sensor 24. When the An / Ca flow rate ratio calculation unit 332 subtracts the cathode gas pressure P _{c_sens} from the anode lower limit pressure P _{a_min} to calculate the inter-electrode differential pressure ΔP _ac , the inter-electrode _space calculated with reference to the flow rate ratio correction map of FIG. A correction factor E _{ac_ps} related to the differential pressure ΔP _ac is calculated.

Then, the An / Ca flow rate ratio calculation unit 332 sets the calculated correction coefficient E _{ac_ps} to the An / Ca flow rate ratio K _{ac_ps_0} when the inter-electrode differential pressure ΔP _ac is zero, using the relationship of equation (6). by multiplying, it calculates the an / Ca flow ratio K _{Ac_ps} corresponding to the machining gap differential pressure [Delta] P _ac.

The An / Ca flow rate ratio calculation unit 332 outputs the calculated An / Ca flow rate ratio _{Kac_ps} to the anode wetting required flow rate calculation unit 333.

The anode wetting required flow rate computing unit 333 computes an anode wetting required flow rate Q a — _rw for targeting the wet state of the electrolyte membrane 111 based on the An / Ca flow rate ratio _{Kac_ps} .

In the present embodiment, the anode wetting required flow rate calculation unit 333 obtains the cathode lower limit flow rate _{Qc_min} from the priority setting unit 310, and the cathode lower limit flow rate _{Qc_min} and the An / Ca flow rate ratio K as shown in the following equation (9). _The anode wetting required flow rate _{Qa_rw} is calculated based on _{ac_ps} .

The anode wetting required flow rate calculation unit 333 outputs the calculated anode wetting required flow rate Q a — _rw to the anode target flow rate setting unit 335.

  The anode lower limit flow rate calculating unit 334 calculates the anode lower limit flow rate according to the operating state of the fuel cell system 100. The anode lower limit flow rate is a lower limit value of the anode gas flow rate set by a requirement different from the wetting requirement of the electrolyte membrane 111.

  For example, the anode lower limit flow rate calculation unit 334 calculates the anode load required flow rate necessary for the power generation of the fuel cell stack 1 based on the required power of the load device 5. In this example, a load required flow rate map indicating the relationship between the stack target current and the anode load required flow rate is recorded in advance in the anode lower limit flow rate calculation unit 334. When the anode lower limit flow rate operation unit 334 acquires the stack target current from the stack target current operation unit 220, the anode lower limit flow rate operation unit 334 refers to the load required flow rate map and calculates the anode load required flow rate associated with the acquired stack target current.

  The anode lower limit flow rate calculation unit 334 outputs the calculated anode load required flow rate to the anode target flow rate setting unit 335 as an anode lower limit flow rate.

The anode target flow rate setting unit 335 _outputs the larger one of the anode lower limit flow rate and the anode wetting required flow rate Q a — _rw to the anode gas supply / discharge device command unit 250 as an anode target flow rate.

As described above, in the anode target flow rate calculation unit 330, in _order to quickly reduce the anode wetting required flow rate _{Qa_rw} when the dry operation is performed, the An / Ca flow rate ratio _{Kac_ps} is decreased from the relationship of equation (9). At the same time, it is necessary to reduce the cathode gas flow rate.

In _order to reduce the An / Ca flow rate ratio _{Kac_ps} , the correction coefficient _{Eac_min} may be reduced, and the cathode outlet relative humidity _{RHc_out_ps} may be reduced from the relationship of the relative humidity / flow rate ratio map shown in FIG. The cathode gas pressure or the anode gas pressure may be reduced to reduce the correction coefficient _{Eac_min} , and the cathode gas flow rate may be reduced to reduce the cathode outlet relative humidity _{RHc_out_ps} .

In the present embodiment, the priority setting unit 310 _outputs the cathode lower limit flow rate Q _{c — min} and the anode lower limit pressure _{Pa — min} as measured values in the dry operation to the anode target flow rate calculation unit 330 as the _wet operation value. As a result, the cathode outlet relative humidity RH _{c_out_ps} in the equation (8) is larger than in the case where measured values of the cathode gas flow rate and the anode gas pressure are used, so the An / Ca flow rate ratio K in the equation (9) _{ac_ps} can be reduced. Furthermore, by using the anode lower limit pressure P a — _min , the correction coefficient E _{ac — min} of the An / Ca flow ratio decreases, so the An / Ca flow ratio K _{ac — ps} further decreases.

Thus, by setting the cathode lower limit flow rate _{Qc_min} as the cathode gas flow rate in the equation (9) while reducing the An / Ca flow rate ratio _{Kac_ps} , the anode wetting required flow rate _{Qa_rw} can be lowered early. .

As described above, in the anode target flow rate calculation unit 330, the cathode outlet relative humidity _{RHc_out_ps} decreases as the cathode wetting required pressure _{Pc_rw} decreases and the cathode gas pressure _{Pc_sens} decreases from the relationship of equation (8). . From the relationship of the relative humidity / flow rate ratio map shown in FIG. 13, the An / Ca flow rate ratio _{Kac_ps} increases and the anode wetting required flow rate _{Qa_rw} increases as the cathode outlet relative humidity _{RHc_out_ps} decreases. That is, since the anode wetting required flow rate Q a — _rw increases as the cathode wetting required pressure P _{c — rw} decreases, the weight loss control for reducing the anode gas circulation flow rate is suppressed.

On the other hand, as the target water balance _{Qw_t} becomes smaller and the target displacement _{Qw_out} becomes larger, the cathode outlet relative humidity _{RHc_out_ps} becomes larger from the relationship of equation (8), so the An / Ca flow ratio _{Kac_ps} becomes smaller, and the anode The required wet flow rate _{Qa_rw} decreases.

As described above, the anode target flow rate calculation unit 330 can decrease the anode target flow rate if the target drainage amount _{Qw_out} does not decrease even in a situation where the cathode gas pressure is lowered in the dry operation. That is, the wetting control unit 300 suppresses the decrease in the circulation flow rate of the anode gas as the pressure in the cathode gas flow path 131 decreases, at least in the dry operation, and as the wettability of the electrolyte membrane 111 increases, the anode gas Circulation flow rate can be reduced.

  FIG. 15 is a block diagram showing an example of a functional configuration of the cathode target flow rate calculation unit 340 when performing the dry operation.

  The cathode target flow rate calculating unit 340 includes a cathode upper limit flow rate calculating unit 341, an / Ca flow rate ratio calculating unit 342, a cathode relative humidity calculating unit 343, a cathode wetting required flow rate calculating unit 344, and a cathode target flow rate setting unit 345. , And a delay circuit 346.

  The cathode upper limit flow rate calculating unit 341 calculates the cathode upper limit flow rate according to the operating state of the fuel cell system 100. The cathode upper limit flow rate is an upper limit value of the cathode gas flow rate set by a requirement different from the wetting requirement of the electrolyte membrane 111.

  For example, the cathode upper limit flow rate calculating unit 341 calculates the cathode load required flow rate necessary for the power generation of the fuel cell stack 1 based on the required power of the load device 5. In this example, a load demand flow rate map indicating the relationship between the stack target current and the cathode load demand flow rate is recorded in advance in the cathode upper limit flow rate calculation unit 341. When the cathode upper limit flow rate operation unit 341 acquires the stack target current from the stack target current operation unit 220, the cathode upper limit flow rate operation unit 341 refers to the load required flow rate map and calculates the cathode load required flow rate associated with the acquired stack target current.

  The cathode upper limit flow rate calculating unit 341 outputs the calculated cathode load required flow rate to the cathode target flow rate setting unit 345 as a cathode upper limit flow rate.

The An / Ca flow rate ratio calculation unit 342 acquires the anode gas circulation flow rate output from the anode gas circulation flow rate estimation unit 230 as the measured value Q a — _sens , and outputs the previous value Q _{c — t — dly} of the cathode target flow rate output from the delay circuit 346. get. An / Ca flow ratio calculation unit 342, based on the cathode target flow rate Q _{C_t_dly} and the anode gas flow Q _{A_sens,} calculates the An / Ca flow ratio _K ac_ct.

Then, the An / Ca flow rate ratio calculation unit 342 acquires the anode lower limit pressure _{Pa_min} from the priority setting unit 310, and acquires the cathode gas pressure _{Pc_sens} from the cathode pressure sensor 24. The An / Ca flow rate ratio calculation unit 342 subtracts the cathode gas pressure P _{c — sens} from the anode lower limit pressure P a — _min to calculate the inter-electrode differential pressure ΔP _{ac — cs} .

After calculating the differential pressure ΔP _{ac_cs} , the An / Ca flow rate ratio calculation unit 342 refers to the flow rate ratio correction map shown in FIG. 12 and calculates the correction coefficient E _{ac_cs} related to the differential pressure ΔP _{ac_cs.} Do. An / Ca flow ratio calculation unit 342, by dividing the An / Ca flow ratio K _{Ac_ct} by the correction factor E _{Ac_cs,} interelectrode differential pressure [Delta] P _ac calculates the An / Ca flow ratio K _{Ac_ct_0} when zero.

The An / Ca flow rate ratio calculating unit 342 outputs the calculated An / Ca flow rate ratio _{Kac_ct_0} to the cathode relative humidity calculating unit 343.

When the cathode relative humidity calculating unit 343 obtains the An / Ca flow ratio _{Kac_ct_0} from the An / Ca flow ratio calculating unit 342, the cathode relative humidity calculating unit 343 refers to the relative humidity / flow ratio map shown in FIG. 13 and an An / Ca flow ratio _{Kac_ct_0.} Calculate the cathode outlet relative humidity _{RHc_out_ct} associated with.

The cathode relative humidity calculation unit 343 outputs the calculated cathode outlet relative humidity _{RHc_out_ct} to the cathode wetting required flow rate calculation unit 344.

The cathode wetting required flow rate calculation unit 344 _sets a cathode for _setting the wet state of the fuel cell stack 1 on the basis of the target drainage amount _{Qw_out} from the target drainage amount calculation unit 323 and the cathode outlet relative humidity _{RHc_out_ct.} The wet required flow rate Q _{c — rw} is calculated.

The cathode wetting required flow rate operation unit 344 acquires the cathode gas pressure P _{c — sens} from the cathode pressure sensor 24, and acquires the saturated water vapor pressure P _sat from the saturated water vapor pressure operation unit 321. Then, the cathode wetting required flow rate calculation unit 344 sets the cathode wetting based on the cathode gas pressure P _{c — sens} , the saturated water vapor pressure P _sat , the target displacement Q _{w — out,} and the cathode outlet relative humidity RH _{c — out ct} as in the following equation (10). The required flow rate _{Qc_rw} is calculated.

The cathode wetting required flow rate calculation unit 344 outputs the calculated cathode wetting required flow rate Q _{c — rw} to the cathode target flow rate setting unit 345.

The cathode target flow rate setting unit 345 sets the smaller one of the cathode wetting required flow rate _{Qc_rw} and the cathode upper limit flow rate from the cathode upper limit flow rate calculating unit 341 as the cathode target flow rate _{Qc_t.} Output to In addition, the cathode target flow rate setting unit 345 outputs the cathode target flow rate _{Qc_t} to the delay circuit 346.

The delay circuit 346 delays the cathode target flow rate _{Qc_t} from the cathode target flow rate setting unit 345 by one cycle of the control cycle. That is, the delay circuit 346 obtains the cathode target flow rate Q _{C_T,} outputs the last cathode target flow rate Q _{C_t_dly} to An / Ca flow ratio calculating unit 342.

  FIG. 16 is a block diagram showing an example of a functional configuration of the anode target pressure calculation unit 350 when performing the dry operation.

  The anode target pressure calculator 350 includes an anode upper limit pressure calculator 351, a cathode relative humidity calculator 352, an An / Ca flow ratio calculator 353, an anode wetting required pressure calculator 354 and an anode target pressure setter 355. including.

  The anode upper limit pressure calculator 351 calculates the anode upper limit pressure according to the operating state of the fuel cell system 100. The anode upper limit pressure is an upper limit value of the anode gas pressure set by a requirement different from the wetting requirement of the electrolyte membrane 111.

  For example, the anode upper limit pressure calculation unit 351 obtains the cathode gas pressure from the cathode pressure sensor 24 and adds the cathode gas pressure to the allowable pressure of the electrolyte membrane 111 to calculate the anode film protection required pressure. Further, the anode upper limit pressure calculator 351 calculates the anode load required pressure based on the required power of the load device 5.

The anode upper limit pressure calculation unit 351 outputs the calculated anode load required pressure, the anode film protection required pressure, and the like to the anode target pressure setting unit 355 as the anode upper limit pressure. The cathode relative humidity calculation unit 352 calculates the target drainage amount calculation unit 323 The target cathode outlet relative humidity _{RHc_out_sens} is calculated on the basis of the target displacement amount _{Qw_out} .

In the present embodiment, the cathode relative humidity calculation unit 352 _acquires the cathode gas pressure P _{c_sens} and the cathode gas flow rate Q _{c_sens} from the cathode pressure sensor 24 and the flow rate sensor 23, respectively, and the saturated water vapor pressure from the saturated water vapor pressure calculation unit 321. Get P _sat .

Then, the cathode relative humidity calculation unit 352 calculates the cathode outlet relative humidity based on the cathode gas pressure P _{c_sens} , the cathode gas flow rate Q _{c_sens} , the saturated water vapor pressure P _sat, and the target displacement Q _{w_out} as in the following equation (11). Calculate RH _{c_out_sens} .

The cathode relative humidity calculating unit 352 outputs the calculated cathode outlet relative humidity RH _{c_out_sens} to the An / Ca flow ratio calculating unit 353.

An / Ca flow ratio calculation unit 353, based on the cathode outlet relative humidity RH _{C_out_sens,} interelectrode differential pressure [Delta] P _ac is calculates An / Ca flow ratio K _{Ac_sens_0} when zero.

An In this embodiment, An / Ca flow ratio calculating unit 353 acquires the cathode outlet relative humidity RH _{C_out_sens,} which refers to the relative humidity / flow ratio map of FIG. 13, associated with the cathode outlet relative humidity RH _{C_out_sens} / Ca flow rate ratio _{Kac_sens_0} is calculated.

Then, the An / Ca flow rate ratio calculation unit 353 acquires the anode gas circulation flow rate output from the anode gas circulation flow rate estimation unit 230 as the measurement value _{Qa_sens} , and acquires the cathode gas flow rate _{Qc_sens} from the flow rate sensor 23. An / Ca flow ratio calculation unit 353, by dividing the anode gas flow Q _{A_sens} by the cathode gas flow rate Q _{C_sens,} calculates the An / Ca flow ratio _K ac_sens.

An / Ca flow ratio calculating section 353, and An / Ca flow ratio K _{Ac_sens,} interelectrode differential pressure [Delta] P _ac outputs and An / Ca flow ratio K _{Ac_sens_0} when the zero anode wetting required pressure calculating unit 354.

The anode wetting required pressure calculating unit 354, and An / Ca flow ratio K _{Ac_sens,} interelectrode differential pressure [Delta] P _ac is based on the An / Ca flow ratio K _{Ac_sens_0} when zero, the target wet state of the electrolyte membrane 111 The anode wet required pressure P a — _rw to _bring it into a state of operation is calculated.

In the present embodiment, the anode wetting required pressure calculating unit 354, as in the following equation (12), and An / Ca flow ratio K _{Ac_sens_0} when interelectrode differential pressure [Delta] P _ac is zero, the actual An / Ca flow ratio A correction coefficient E _{ac_sens} is calculated based on K _{ac s sens} .

When the correction coefficient E _{ac — sens} is calculated, the anode wetting required pressure calculation unit 354 calculates the inter-electrode differential pressure P _{ac — sens} related to the correction coefficient E _{ac — sens} with reference to the flow ratio correction map shown in FIG. The anode wetting required pressure calculation unit 354 calculates the anode wetting required pressure P a — _rw based on the inter-electrode differential pressure P _{ac — sens} and the cathode gas pressure P _{c — sens} as in the following formula (13).

The anode wetting required pressure calculation unit 354 outputs the anode wetting required pressure P a — _rw to the anode target pressure setting unit 355.

Anode target pressure setting unit 355 _{outputs a} smaller value of anode wet required pressure P a — _rw and anode upper limit pressure from anode upper limit pressure calculation unit 351 to anode gas supply / discharge device command unit 250 as anode target pressure. Do.

  FIG. 17 is a flowchart showing an example of a processing procedure related to a control method of the controller 200 provided with the wetting control unit 300 in the present embodiment. The processing procedure of this control method is repeatedly executed in a predetermined cycle.

  The controller 200 detects the operating state of the fuel cell stack 1 in step S1. In the present embodiment, the impedance measuring device 6 shown in FIG. 1 detects the HFR of the fuel cell stack 1 according to the instruction of the controller 200, the flow sensor 23 detects the cathode gas flow, and the cathode pressure sensor 24 detects the cathode gas pressure. To detect

  In step S2, the stack target current calculation unit 220 of the controller 200 acquires the required power from the load device 5, and calculates the stack target current based on the required power of the load device 5.

  In step S3, the controller 200 acquires the measured value of the cathode gas flow rate from the flow rate sensor 23, acquires the measured value of the cathode gas pressure from the cathode pressure sensor 24, and acquires the measured value of the anode gas pressure from the anode pressure sensor 37. Do. Furthermore, the anode gas circulation flow rate estimation unit 230 of the controller 200 estimates the anode gas circulation flow rate based on the rotational speed of the anode circulation pump 36 as in equation (1). Further, the saturated water vapor pressure calculation unit 321 of the wetting control unit 300 acquires the stack inlet water temperature and the stack outlet water temperature from the inlet water temperature sensor 46 and the outlet water temperature sensor 47, respectively, and calculates an average value obtained by averaging both temperatures as the stack temperature.

  In step S4, the membrane wet state acquiring unit 210 of the controller 200 acquires, from the impedance measuring device 6, a measured HFR that is correlated with the wet state of the electrolyte membrane 111.

  In step S5, the controller 200 calculates a target HFR for maintaining the power generation performance of the fuel cell stack 1. In the present embodiment, the target HFR operation unit 211 shown in FIG. 7 obtains the stack output current from the current sensor 51, and is related to the obtained stack output current using the target HFR map shown in FIG. Calculate the target HFR.

  In step S6, the controller 200 calculates a target water balance for compensating for excess or deficiency of water of the electrolyte membrane 111 so that the measured HFR converges to the target HFR. In the present embodiment, the target water balance calculation unit 212 shown in FIG. 7 calculates the target water balance based on the target HFR and the measured HFR.

  In step S7, the controller 200 determines, based on the wet state of the electrolyte membrane 111, whether or not to carry out the dry operation. In the present embodiment, the priority setting unit 310 shown in FIG. 10 determines whether the measured HFR has reached a predetermined lower limit, and the dry operation is performed when the measured HFR reaches the lower limit. It is determined that

  When it is determined in step S8 that the dry operation is not performed, the controller 200 performs the normal wet control process. For example, the controller 200 uses the measured values of the flow and pressure of the anode gas and the measured values of the flow and pressure of the cathode gas based on the target water balance, the flow and pressure of the anode gas, the flow of the cathode gas and Control the pressure.

  If it is determined in step S10 that the dry operation is to be performed, the wetness control unit 300 of the controller 200 executes the dry operation process. When the dry operation processing in step S10 is completed, a series of processing procedures for the control method of the controller 200 are completed. Next, dry operation processing will be described in detail with reference to FIG.

  FIG. 18 is a flowchart showing an example of the processing procedure related to the dry operation processing executed in step 10.

  In step S11, the priority setting unit 310 of the wetting control unit 300 calculates the cathode lower limit flow rate, the cathode upper limit pressure, and the anode lower limit pressure as priority control parameters for setting priorities for each control of the anode gas and the cathode gas. These parameters are the wet operation values when the electrolyte membrane 111 is in the most wet state.

  In step S12, as described in FIG. 11, the cathode target pressure calculation unit 320 of the wetting control unit 300 determines the target water balance and the upper limit anode flow rate, the lower limit anode pressure, and the lower limit cathode flow which are priority control parameters. Calculate the cathode target pressure. By setting three priority control parameters in the cathode target pressure calculation unit 320, the priority of the step-down control for lowering the cathode gas pressure is the highest.

  For this reason, the cathode target pressure calculation unit 320 determines that three controls of cathode gas flow control, anode gas flow control, and anode gas pressure control are not performed at all in the dry operation, and this is better than normal wetting control. Reduce the cathode target pressure quickly.

  In step S13, the anode target flow rate calculation unit 330 of the wetting control unit 300 calculates the target water balance, the cathode gas pressure, and the cathode lower limit flow rate and the anode upper limit flow rate, which are priority control parameters, as described in FIG. Calculate the anode target flow rate. By setting two priority control parameters in the anode target flow rate calculation unit 330, the priority of the weight reduction control for reducing the anode gas circulation flow rate is second highest.

  For this reason, the anode target flow rate calculation unit 330 determines that two controls of cathode gas flow rate control and anode gas pressure control are not performed at all in the dry operation, and makes the anode target flow rate quicker than normal wetting control. Lower.

  In step S14, the cathode target flow rate calculation unit 340 of the wetting control unit 300 determines the cathode as described in FIG. 15 based on the target water balance, the cathode gas pressure and the anode gas flow rate, and the anode lower limit pressure which is a priority control parameter. Calculate the target flow rate. By setting one priority control parameter in the cathode target flow rate calculation unit 340, the priority of the increase control for increasing the cathode gas flow rate is the third highest. Therefore, the cathode target flow rate calculation unit 340 determines that only the anode gas pressure control is not performed at all in the dry operation, and raises the cathode target flow rate more quickly than the normal wetting control.

  In step S15, the anode target pressure calculation unit 350 of the wetting control unit 300 calculates the anode target pressure as described in FIG. 16 based on the target water balance, the cathode gas flow rate, the cathode gas pressure, and the anode gas flow rate. Do. Since the priority control parameter is not used, the anode target pressure calculator 350 raises the anode target pressure as in the normal wetting control. Therefore, the priority of boosting control for raising the anode gas pressure is the fourth.

  In step S20, the cathode gas supply / discharge device command unit 240 and the anode gas supply / discharge device command unit 250 of the controller 200 perform the gas conditioning process based on the cathode target pressure, the anode target flow rate, the cathode target flow rate, and the anode target pressure. Run. The gas conditioning process will be described in detail with reference to FIG. When the gas state adjustment process is completed in step S20, the process returns to the dry operation process shown in FIG.

  FIG. 19 is a flow chart showing an example of the processing procedure related to the gas state adjustment processing executed in step 20.

  In step S211, the controller 200 increases the opening degree of the cathode pressure regulating valve 26 so that the cathode gas pressure converges to the cathode target pressure. This lowers the cathode gas pressure.

  In step S212, the controller 200 determines whether the measured HFR has reached the target HFR. If the measured HFR has reached the target HFR, the gas conditioning process ends.

  In step S213, the controller 200 determines whether the cathode gas pressure has reached the cathode lower limit pressure when the measured HFR has not reached the target HFR, and when the cathode gas pressure has not reached the cathode lower limit pressure, the controller 200 performs step S211. Return to the processing of

  In step S221, when the cathode gas pressure reaches the cathode lower limit pressure, the controller 200 reduces the rotational speed of the anode circulation pump 36 so that the anode gas circulation flow rate converges to the anode target flow rate. This reduces the anode gas circulation flow rate.

  In step S222, the controller 200 determines whether the measured HFR has reached the target HFR. If the measured HFR has reached the target HFR, the gas conditioning process ends.

  In step S223, if the measured HFR has not reached the target HFR, the controller 200 determines whether or not the anode gas circulation flow has reached the anode lower limit flow, and if it has not reached the anode lower limit flow, the step It returns to the process of S221.

  In step S231, when the anode gas circulation flow rate reaches the anode lower limit flow rate, the controller 200 increases the rotational speed of the compressor 22 so that the cathode gas flow rate converges on the cathode target flow rate. Thereby, the cathode gas flow rate is increased.

  In step S232, the controller 200 determines whether the measured HFR has reached the target HFR. If the measured HFR has reached the target HFR, the gas conditioning process ends.

  In step S233, when the measured HFR has not reached the target HFR, the controller 200 determines whether or not the cathode gas flow has reached the cathode upper limit flow, and in the case where the cathode upper limit flow has not been reached, step S231. Return to the processing of

  In step S241, when the cathode gas flow rate reaches the cathode upper limit flow rate, the controller 200 increases the opening degree of the anode pressure regulating valve 33 so that the anode gas pressure converges to the anode target pressure. This causes the anode gas pressure to rise.

  In step S242, the controller 200 determines whether the measured HFR has reached the target HFR. If the measured HFR has reached the target HFR, the gas conditioning process ends.

  In step S243, when the measured HFR has not reached the target HFR, the controller 200 determines whether the anode gas pressure has reached the anode upper limit pressure. If the anode gas pressure has not reached the anode upper limit pressure, the controller 200 returns to the process of step S241 and raises the anode gas pressure.

  Then, if the measured HFR has reached the target HFR in step S242, or if the anode gas pressure has reached the anode upper limit pressure in step S243, the gas condition adjustment processing is completed, and the process of step S20 shown in FIG. Return to dry operation processing.

  FIG. 20 is a time chart showing changes in the operating state of the fuel cell system 100 in the dry operation of the present embodiment.

  FIG. 20A shows a change in measured HFR of the fuel cell stack 1. FIGS. 20 (B) and 20 (D) are diagrams showing changes in pressure and flow rate of the cathode gas supplied to the fuel cell stack 1. FIGS. 20C and 20E are diagrams showing changes in the flow rate and pressure of the anode gas supplied to the fuel cell stack 1. The horizontal axes of the respective drawings from FIG. 20 (A) to FIG. 20 (E) are common time axes.

  At time t20, as shown in FIG. 20A, for example, the required power of the load device 5 is significantly reduced after acceleration of the vehicle, and the target HFR is significantly increased. Along with this, the priority setting unit 310 determines that the dry operation is performed, and calculates the wet operation value as the priority control parameter.

  Then, the priority setting unit 310 sets the cathode lower limit flow rate, the anode upper limit flow rate, and the anode lower limit pressure, which are WET operation values, to the cathode target pressure calculation unit 320 instead of the measurement value. Furthermore, the priority setting unit 310 sets the cathode lower limit flow rate and the anode lower limit pressure for the anode target flow rate calculation unit 330, and sets the anode lower limit pressure for the cathode target flow rate calculation unit 340. That is, in the dry operation, the priority setting unit 310 sets priorities for control in the order of cathode gas pressure control, anode gas flow control, cathode gas flow control, and anode gas pressure control.

  As a result, as shown in FIG. 20 (B), the cathode pressure control valve 26 is opened by the cathode target pressure calculation unit 320 prior to other controls to lower the cathode gas pressure. Along with this, the amount of water flowing from the cathode gas passage 131 into the anode gas passage 121 decreases, and the amount of anode circulating water decreases, so that the measured HFR rises toward the target HFR as shown in FIG. .

  As described above, in the dry operation, first, the cathode pressure regulating valve 26 with a small response delay is driven by executing the step-down control to lower the cathode gas pressure, so that the water content of the electrolyte film 111 can be reduced rapidly. it can.

  At time t21, as shown in FIGS. 20B and 20C, since the cathode gas pressure reaches the lower limit value of the dry operation, the anode target flow rate calculation unit 330 complements the cathode gas step-down control. The rotational speed of the circulation pump 36 is reduced to reduce the anode gas circulation flow rate. Along with this, the amount of anode circulating water decreases, so that the measured HFR further rises toward the target HFR as shown in FIG. 20 (A).

  Thus, in the dry operation, power consumption of the anode circulation pump 36 can be reduced by executing the decrease control for reducing the anode gas circulation flow rate secondly. Therefore, by reducing the anode gas circulation flow rate after lowering the cathode gas pressure, it is possible to suppress the power consumption of the fuel cell system 100 while securing the responsiveness.

  At time t22, as shown in FIGS. 20C and 20D, the anode gas circulation flow rate reaches the upper limit value of the dry operation, so that the cathode target flow rate calculation unit 340 complements the anode gas amount reduction control. The rotational speed of the compressor 22 is increased to increase the cathode gas flow rate. Along with this, the amount of drainage carried out to the outside from the cathode gas flow path 131 by the cathode gas increases, so the amount of anode circulating water decreases, and the measured HFR further rises toward the target HFR as shown in FIG. Do.

  Thus, in the dry operation, thirdly, by performing the increase control to increase the flow rate of the cathode gas, the water content of the electrolyte film 111 is rapidly reduced while the opportunity for the power consumption of the compressor 22 is increased as much as possible. be able to.

  At time t23, as shown in FIGS. 20D and 20E, since the cathode gas flow rate reaches the upper limit value of the dry operation, the anode target pressure calculation unit 350 complements the cathode gas amount increase control. The pressure control valve 33 is opened to increase the anode gas pressure. Along with this, the partial pressure of water vapor in the anode gas flow channel 121 increases, and the amount of water flowing from the cathode gas flow channel 131 into the anode gas flow channel 121 decreases, so the amount of anode circulating water decreases, as shown in FIG. As shown in), the measured HFR further rises toward the target HFR.

  Thus, in the dry operation, fourthly, by executing boost control to raise the anode gas pressure, the responsive anode pressure regulation valve 33 is driven, so that the responsiveness of the cathode gas increase control by the compressor 22 is improved. We can make up for bad things quickly.

  At time t24, as shown in FIG. 20 (E), the anode gas pressure reaches the upper limit value of the dry operation, and as shown in FIG. 20 (A), the measured HFR reaches the target HFR.

  As described above, in the dry operation, by controlling each of the cathode gas pressure, the anode gas circulation flow rate, the cathode gas flow rate, and the anode gas pressure in this order, the electrolyte membrane can be rapidly reduced while suppressing the power consumption of the fuel cell system 100. The water content of 111 can be reduced.

  In FIG. 20B, the cathode gas pressure is lowered to the lower limit set by the wetting requirement of the electrolyte membrane 111, but the cathode gas pressure is set at the lower limit set by the requirement different from the wetting requirement of the electrolyte membrane 111. May be limited.

  FIG. 21 is a time chart showing a change in the operating state of the fuel cell system 100 when the cathode gas pressure reduction control is limited due to a demand different from the wet demand in the dry operation.

  FIG. 21A shows a change in the target HFR of the fuel cell stack 1. 21 (B) and 21 (C) are diagrams showing changes in cathode gas pressure and anode gas circulation flow rate, respectively. FIG. 21 (D) is a diagram showing a change in the amount of anode circulating water. The horizontal axes of these drawings are time axes common to one another.

  Here, the dry operation of the present embodiment is shown by a solid line, and the anode target flow rate calculation unit 330 shown in FIG. 10 calculates the anode target flow rate using the cathode wetting required pressure instead of the measured value of the cathode gas pressure. The dry operation of is illustrated by the dotted line.

  At time t30, as shown in FIG. 21A, the target HFR significantly increases. Then, as shown in FIG. 21B, the cathode gas pressure decreases.

  At time t31, the cathode gas pressure reaches the lower limit pressure set by the demand different from the wet demand, so that as shown by the solid line in FIG. 21B, the step-down control of the cathode gas in the dry operation is limited. This lower limit pressure is, for example, the calculation result of the cathode lower limit pressure calculator 327 shown in FIG.

  In this embodiment, since the anode target flow rate calculation unit 330 calculates the anode target flow rate using the measured value of the gaso gas pressure, as shown by the solid line in FIG. 21C, immediately after the step-down control of the cathode gas is limited. The anode gas circulation flow rate decreases. That is, the control for reducing the amount of anode gas is executed such that the portion where the wet state of the electrolyte film 111 can not be manipulated can be compensated by the step-down control of the cathode gas. Therefore, as shown by the solid line in FIG. 21A, the measurement HFR can be raised even immediately after the cathode gas pressure reduction control is limited.

  Assuming that the anode target flow rate calculation unit 330 calculates the anode target flow rate using the calculation result of the cathode wetting required pressure calculation unit 326 shown in FIG. 11, from time t31 as shown by a dotted line in FIG. Until time t32, the anode gas reduction control is not performed. As a result, as shown by the dotted line in FIG. 21A, since the target HFR is not reached at time t33, the time required to complete the dry operation becomes long.

  As described above, in the present embodiment, since the anode target flow rate calculation unit 330 calculates the anode target flow rate using the measured value of the cathode gas pressure, the time required for the dry operation is higher than when the cathode wetting required pressure is used. Can be shortened.

  FIG. 22 is a time chart showing changes in the operating state of the fuel cell system 100 in the dry operation when the target HFR sharply rises.

  FIG. 22A shows a change in target HFR. The vertical axes of the respective drawings from FIG. 22 (B) to FIG. 22 (D) are the same as the vertical axes of the respective drawings from FIG. 21 (B) to FIG. 21 (D). The horizontal axes of the drawings up to 22 (D) are common time axes.

  In FIG. 22 (B), the measured value of the cathode gas pressure is indicated by a solid line, and the cathode target pressure is indicated by a broken line.

  At time t40, as shown in FIG. 22A, the target HFR rises in a pulsed manner. In such a situation, for example, when the required power of the load device 5 becomes extremely small due to the switching of the vehicle from the acceleration state to the deceleration state, the target HFR significantly increases due to the characteristics of FIG. .

  As indicated by the broken line in FIG. 22B, the cathode target pressure calculation unit 320 calculates the cathode target pressure that can achieve the target HFR. On the other hand, the cathode gas pressure is gradually reduced compared to the cathode target pressure due to the volume of the fuel cell stack 1, piping resistance and the like.

  Immediately after time t40, since the deviation between the cathode gas pressure and the cathode target pressure is large, the drying operation by the step-down control of the cathode gas is not sufficiently performed. As a result, the anode target flow rate calculation unit 330 lowers the anode target flow rate so as to complement the difference between the cathode gas pressure and the cathode target pressure, so the anode gas circulation flow rate decreases as shown in FIG. 22 (C).

  As time passes from time t40, the difference between the cathode gas pressure and the cathode target pressure becomes smaller. Therefore, as shown in FIG. Raise Thus, the transiently decreased anode gas circulation flow rate starts to rise.

  At time t41, as shown in FIG. 22 (B), the cathode gas pressure reaches the cathode target pressure, and as shown in FIG. 22 (C), the anode gas circulation flow rate slightly rises and then becomes steady state.

  As described above, when the target HFR significantly increases, the wetting control unit 300 slightly delays the cathode gas pressure reduction control, and thus executes the anode gas weight loss control by that amount. That is, in the dry operation in the transient state, the wetting control unit 300 decreases the cathode gas pressure and reduces the anode gas circulation flow rate so that the difference between the target HFR and the measurement HFR becomes smaller.

  As described above, when it is necessary to reduce the water content of the electrolyte film 111 promptly, the anode gas weight reduction control is performed so as to supplement the portion where the water content of the electrolyte film 111 does not decrease even if the pressure reduction control of the cathode gas is performed. Be done. As a result, the water content of the electrolyte membrane 111 can be reduced efficiently and promptly.

  According to the second embodiment of the present invention, the moisture control unit 300 reduces the water content of the electrolyte membrane 111 by the operation of the cathode pressure control valve 26 when the operation of the cathode pressure control valve 26 is prioritized and controlled at least during the dry operation. If not, the operation of the anode circulation pump 36 is controlled to compensate for the non-decreased portion. That is, when performing the step-down control to lower the cathode gas pressure when the dry operation is performed, if the water content of the electrolyte membrane 111 is not reduced even if the pressure reduction control is performed, the anode gas circulation flow rate is reduced to compensate the non-reduction portion. Execute control. As a result, as shown in FIG. 21C, the decrease control of the anode gas is executed so as to supplement the step-down control of the cathode gas, so that the increase in the time required for the dry operation can be reduced.

  Furthermore, according to the present embodiment, the cathode target pressure calculation unit (pressure control unit) 320 of the wetting control unit 300 is based on the measured HFR and the anode gas circulation flow rate that are correlated with the wetness of the electrolyte membrane 111. The pressure control valve 26 is used to control the cathode gas pressure. Then, the anode target flow rate calculation unit (flow rate control unit) 330 of the wetting control unit 300 controls the anode gas circulation flow rate using the anode circulation pump 36 based on the measured HFR and the cathode gas pressure.

  Then, the priority setting unit (priority setting unit) 310 sets a target water balance based on the WET operation value, which is the anode gas flow rate when making the electrolyte membrane 111 in a wet state higher than the present, at least at the time of the dry operation. Are set in the cathode target pressure calculation unit 320. At the same time, the priority setting unit 310 sets the measured value of the cathode gas pressure and the target water balance in the anode target flow rate calculation unit 330. Thereby, in the dry operation, the priority of the step-down control of the cathode gas can be made higher than the priority of the control of the decrease of the anode gas.

  Further, according to the present embodiment, the anode gas flow rate when the electrolyte membrane 111 is wetted higher than the present time in the dry operation is set to the largest flow rate as long as the performance of the fuel cell 10 can be secured. Thereby, in the dry operation, the cathode gas pressure can be reduced more quickly.

  Further, according to the present embodiment, when performing the dry operation, the anode target flow rate calculation unit 330 suppresses the decrease in the anode gas circulation flow rate as the cathode gas pressure decreases, while wetting the electrolyte membrane 111. As the degree increases, the anode gas circulation flow rate decreases. Thereby, in the decrease control of the anode gas, the dry operation by the step-down control of the cathode gas can be complemented early.

  Further, according to the present embodiment, as shown in FIG. 20, when performing the dry operation, the priority setting unit 310 of the wetting control unit 300 performs cathode gas pressure control, anode gas flow control, and cathode gas. Each control is executed in the order of flow rate control and anode gas pressure control.

  For this reason, since step-down control of the cathode gas is executed prior to weight loss control of the anode gas, it is possible to quickly start the dry operation and to execute the weight loss control of the anode gas in a situation not contributing to the dry operation. It can be avoided. Further, since the decrease control of the anode gas is executed prior to the increase control of the cathode gas, it is possible to suppress the increase of the power consumption of the compressor 22 while reducing the power consumption of the anode circulation pump 36. That is, the dry operation can be performed promptly and accurately while suppressing the power consumption of the fuel cell system 100. Furthermore, the amount increase control of the cathode gas is executed prior to the pressure increase control of the anode gas, so the water content of the electrolyte film 111 can be effectively reduced.

  In the present embodiment, when performing the dry operation, the step-down control of the cathode gas is executed with priority over the reduction control of the anode gas, but when the required power of the load device 5 is large, Both are often restricted. For this reason, when the required power of the load device 5 is large, the dry operation may not function effectively. Therefore, it is preferable to execute under the condition that the step-down control and the decrease control are not easily restricted.

Third Embodiment
FIG. 23 is a flow chart showing an example of a processing procedure relating to the control method of the fuel cell system 100 in the third embodiment of the present invention.

  The control method of the present embodiment includes the process of step S30 in addition to the processes of the control method shown in FIG. Here, only the process of step S30 will be described, and the other processes are the same as the processes shown in FIG.

  In step S30, when it is determined that the dry operation is performed in step S7, the priority setting unit 310 illustrated in FIG. 10 acquires the stack target current from the stack target current calculation unit 220 illustrated in FIG. Do. Then, the priority setting unit 310 determines whether the stack target current is smaller than a predetermined threshold Th. The predetermined threshold Th is set to a current value at which it is difficult to limit the step-down control of the cathode gas and the reduction control of the anode gas in the dry operation processing in step S10 due to other requirements. For example, the predetermined threshold Th is set such that the dry operation process is performed when the fuel cell stack 1 is in a low load operation.

  If the stack target current is smaller than the threshold Th, the process proceeds to step S10. If the stack target current is greater than or equal to the threshold Th, the process proceeds to step S8.

  As described above, according to the third embodiment of the present invention, the dry operation process of step S10 is performed only when the generated power of the fuel cell stack 1 is low, so that the cathode gas pressure reduction control and the anode gas weight reduction control Is hard to be restricted, and dry operation processing can be performed effectively.

  Next, a configuration example of the impedance measuring device 6 in the above embodiment will be described.

  FIG. 24 is a block diagram showing an example of the configuration of the impedance measuring device 6.

  The impedance measuring device 6 is connected to the middle terminal 1C in addition to the positive electrode terminal (cathode electrode side terminal) 1B and the negative electrode terminal (anode electrode side terminal) 1A of the fuel cell stack 1. The portion connected to the halfway terminal 1C is grounded.

  The impedance measuring device 6 measures the positive electrode side voltage measurement sensor 61 for measuring the positive electrode side AC potential difference V1 of the positive electrode terminal 1B relative to the halfway terminal 1C and the negative electrode side voltage measurement measuring the negative electrode side AC potential difference V2 of the negative electrode terminal 1A relative to the halfway terminal 1C. And a sensor 62.

  Furthermore, the impedance measuring device 6 applies an alternating current I2 to the circuit consisting of the positive electrode side alternating current power supply 63 for applying the alternating current I1 to the circuit consisting of the positive electrode terminal 1B and the halfway terminal 1C, and the negative electrode terminal 1A and the halfway terminal 1C. The inside of the fuel cell stack 1 based on the negative electrode side AC power supply unit 64, the controller 65 for adjusting the amplitude and phase of the alternating current I1 and the alternating current I2, and the positive electrode side alternating potential difference V1 and V2 and the alternating currents I1 and I2. And an impedance calculator 66 for calculating the impedance Z.

  The controller 65 adjusts the amplitudes and phases of the alternating current I1 and the alternating current I2 so that the positive side alternating potential difference V1 and the negative side alternating potential difference V2 become equal.

  The impedance calculation unit 66 includes hardware components such as an AD converter and a microcomputer chip (not shown), and software components such as a program for calculating the impedance.

  The impedance calculation unit 66 divides the positive electrode side alternating potential difference V1 by the alternating current I1 to calculate the internal impedance Z1 from the halfway terminal 1C to the positive electrode terminal 1B, divides the negative side alternating potential difference V2 by the alternating current I2, The internal impedance Z2 from the halfway terminal 1C to the negative electrode terminal 1A is calculated. Furthermore, the impedance calculation unit 66 calculates the total impedance Z of the fuel cell stack 1 by taking the sum of the internal impedance Z1 and the internal impedance Z2.

  According to the present embodiment, the impedance measuring device 6 is connected to the fuel cell stack 1, and outputs alternating current powers I 1 and I 2 to the fuel cell stack 1, and positive electrodes of the fuel cell stack 1. The potential difference between positive side AC potential difference V1 which is the potential difference obtained by subtracting the potential of mid portion 1C from the potential of side 1B and the negative potential which is the potential difference obtained by subtracting the potential of mid portion 1C from the potential of negative side 1A of fuel cell stack 1 Controller 65 as an AC adjustment unit that adjusts AC currents I1 and I2 based on side AC potential difference V2, fuel based on adjusted AC currents I1 and I2, positive side AC potential difference V1 and negative side AC potential difference V2 And an impedance calculation unit 66 that calculates the impedance Z of the battery stack 1.

  The controller 65 applies the alternating current I1 and the negative electrode applied by the positive electrode AC power supply 63 so that the positive electrode AC potential difference V1 on the positive electrode side of the fuel cell stack 1 substantially matches the negative electrode AC potential difference V2 on the negative electrode side. The amplitude and the phase of the alternating current I2 applied by the side alternating current power supply unit 64 are adjusted. As a result, the amplitude of positive electrode side alternating current potential difference V1 and the amplitude of negative electrode side alternating potential difference V2 become equal, so that positive electrode terminal 1B and negative electrode terminal 1A become substantially equal potential (this is referred to as equal potential control in the following). ). Therefore, the flow of alternating currents I1 and I2 for impedance measurement to the load device 5 is prevented, and the generation of power by the fuel cell 10 is prevented from being affected.

  Further, even if the fuel cell stack 1 is in the power generation state, the measurement AC potential is superimposed on the voltage generated by the power generation, so the values of the positive electrode side AC potential difference V1 and the negative electrode side AC potential difference V2 become large. However, since the phases and amplitudes of the positive electrode side alternating potential difference V1 and the negative side alternating potential difference V2 themselves do not change, it is possible to perform highly accurate impedance measurement as in the case where the fuel cell 10 is not generating electricity.

  Furthermore, various modifications can be made to the circuit configuration for measuring the impedance Z and the like. For example, the fuel cell stack 1 may be supplied with an alternating current from a predetermined current source, and the output alternating voltage may be measured, and the impedance may be calculated based on the alternating current and the output alternating voltage.

  As mentioned above, although each embodiment of the present invention was described, the above-mentioned embodiment showed only a part of application example of the present invention, and the technical scope of the present invention is limited to the concrete composition of the above-mentioned embodiment. is not.

For example, in the present embodiment, the membrane wet state acquisition unit 210 calculates the target water balance _{Qw_t} and outputs it to the wetting control unit 300. However, the target drainage amount _{Qw_out} is calculated based on the calculated target water balance _{Qw_t} . The target displacement Q _{w_out} may be output instead of the target water balance _{w_t} .

  In addition, the said embodiment can be combined suitably.

1 Fuel cell stack (stacked battery)
2 Cathode gas supply and discharge device (oxidant system)
3 Anode gas supply and discharge device (fuel system)
6 Impedance measuring device (measuring device)
10 fuel cell 22 compressor (draining means)
26 Cathode pressure regulator (oxidant system pressure regulator, pressure regulator)
36 Anode circulation pump (actuator)
37 anode circulation passage (circulation passage)
66 Controller (AC controller)
66 impedance calculator (calculator)
100 fuel cell system 111 electrolyte membrane 121 anode gas flow path (fuel flow path)
131 Cathode gas channel (oxidant channel)
200 controller (moisture control device)
210 Wet state acquisition unit (acquisition means)
300 Wet control unit (control means)
320 Cathode Target Pressure Calculator (Pressure Controller)
330 Anode target flow rate calculation unit (flow rate control unit)

Claims (11)

A drainage means provided in an oxidant system in which an oxidant for power generation of a fuel cell flows, and draining water generated at an electrolyte membrane of the fuel cell by the oxidant supply means for supplying the oxidant to the fuel cell;
A fuel circulation unit that is provided in a fuel system that holds fuel generated in the electrolyte membrane and that circulates the fuel in the fuel system; and the fuel flows in the direction opposite to the flow of the oxidant system;
An oxidant system pressure adjusting means for adjusting the pressure of the oxidant system;
Acquisition means for acquiring a signal indicating a wet state of the electrolyte membrane;
Control means for operating at least the fuel circulation means and the oxidant system pressure adjustment means according to the signal acquired by the acquisition means to control the wet state of the electrolyte membrane;
The control means controls the oxidant-based pressure control means prior to the fuel circulation means at least during a dry operation to reduce the water content of the electrolyte membrane.
Fuel control system for a fuel cell system characterized by The fuel cell system wetness control device according to claim 1, wherein
When the control means preferentially controls the operation of the oxidizing agent pressure adjusting means at least at the time of the dry operation, when the water content of the electrolyte membrane is not reduced by the operation of the oxidizing agent pressure adjusting means, the control means Control the operation of the fuel circulation means to compensate for the non-decreasing portion;
Fuel control system for a fuel cell system characterized by A fuel cell system wetness control device according to claim 1 or claim 2, comprising:
The control means
A pressure control unit that controls the pressure of the oxidant system based on the wettability of the electrolyte membrane and the flow rate of fuel circulating through the fuel system;
A flow rate control unit that controls the flow rate of fuel circulating through the fuel system based on the wetness of the electrolyte membrane and the pressure of the oxidant system;
At least in the dry operation, the flow rate of fuel when making the electrolyte membrane more wet than the present time is set to the pressure control unit, and the pressure of the oxidant system is set to the flow control unit. Including a priority setting unit,
Fuel control system for a fuel cell system characterized by A fuel cell system wetness control device according to claim 3, wherein
The flow rate of fuel when the electrolyte membrane is in a wet state higher than the present time is set to the highest flow rate within the range in which the performance of the fuel cell can be ensured.
Fuel control system for a fuel cell system characterized by A fuel cell system wetness control device according to claim 3 or claim 4, comprising:
The control means, when the fuel circulation means does not operate at the time of the dry operation, the fuel when the flow rate of the fuel set in the pressure control unit makes the electrolyte membrane more wet than at present Switching from the flow rate of fuel to the flow rate of fuel circulating in the fuel system,
Fuel control system for a fuel cell system characterized by A fuel cell system wetness control device according to any one of claims 1 to 5, wherein
The fuel cell is
An oxidant channel for passing an oxidant to one surface of the electrolyte membrane;
A fuel flow path for passing fuel in a direction opposite to the direction of the oxidant flowing in the oxidant flow path with respect to the other surface of the electrolyte membrane;
The oxidizing agent system pressure adjusting means includes a pressure regulating valve that regulates the pressure of the oxidizing agent supplied to the oxidizing agent flow passage, and changes the pressure of the oxidizing agent flow passage by changing the opening degree of the pressure regulating valve. Go up and down,
The control means lowers the pressure of the oxidant flow channel at least when the amount of water circulating through the fuel flow channel is reduced during the dry operation.
Fuel control system for a fuel cell system characterized by 7. The fuel cell system wetness control device according to claim 6, wherein
The fuel circulation means is
A circulation passage for introducing and circulating the fuel discharged from one end of the fuel passage to the other end of the fuel passage, and an actuator provided in the circulation passage for adjusting the circulation flow rate of the gas containing the fuel Including
By changing the rotational speed of the actuator, the circulation flow rate of the gas flowing through the circulation passage can be increased or decreased.
The control means reduces the circulation flow rate of the gas at least when the amount of water circulating in the circulation passage is reduced at the time of the dry operation.
Fuel control system for a fuel cell system characterized by 8. A fuel cell system wetness control device according to claim 7, wherein
The control means suppresses the decrease in the circulation flow rate of the gas as the pressure in the oxidant channel decreases, at least in the dry operation, and the circulation of the gas as the wettability of the electrolyte membrane increases. Reduce the flow rate,
Fuel control system for a fuel cell system characterized by A fuel cell system wetness control device according to any one of claims 1 to 8, wherein
The control means controls each state amount prior to the pressure of the oxidant system, the flow rate of the fuel system, the flow rate of the oxidant system, and the pressure of the fuel system at least at the time of the dry operation.
Fuel control system for a fuel cell system characterized by A fuel cell system wetness control device according to any one of claims 1 to 9,
The fuel cell is composed of a laminated cell,
The fuel cell system further includes a measuring device connected to the laminated cell to output an alternating current to the laminated cell.
The potential difference of the positive electrode side which is the potential difference obtained by subtracting the potential of the middle part of the laminated cell from the potential of the positive electrode side of the laminated cell An alternating current adjustment unit that adjusts an alternating current based on the negative electrode side alternating potential difference which is a potential difference;
A calculation unit that calculates the impedance of the laminated battery based on the alternating current adjusted by the alternating current adjustment unit, the positive electrode side alternating potential difference, and the negative electrode side alternating potential difference;
The acquisition means acquires, as the signal, the impedance of the laminated battery calculated by the calculation unit.
Fuel control system for a fuel cell system characterized by A water draining means for draining water generated at an electrolyte membrane of the fuel cell by an oxidant supplied by an oxidant supplying means provided in an oxidant system for flowing an oxidant into the fuel cell;
A fuel circulating unit that is provided in a fuel system that flows fuel in a direction opposite to the flow of the oxidant system, holds water generated by the electrolyte membrane, and circulates the fuel to the fuel system;
An oxidant system pressure adjusting means for adjusting the pressure of the oxidant system;
Acquisition means for acquiring a signal indicating a wet state of the electrolyte membrane;
A control unit configured to control at least the fuel circulation unit and the oxidant system pressure adjustment unit according to the signal acquired by the acquisition unit to control the wet state of the electrolyte membrane; Method,
At least in the dry operation for reducing the water content of the electrolyte membrane, the oxidant-based pressure adjusting means is controlled with priority over the fuel circulating means.
Method of controlling wetness of fuel cell system characterized in that.

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