JP6171572B2 - Fuel cell system - Google Patents

Description

  The present invention relates to a fuel cell system for warming up a fuel cell at low temperature startup.

  2. Description of the Related Art There is known a fuel cell system that supplies a cathode gas and an anode gas to a fuel cell and generates power according to a load. For this fuel cell, generally around 70 ° C. is a temperature range suitable for power generation. Therefore, it is desirable to quickly raise the temperature of the fuel cell to a temperature range suitable for power generation after starting the fuel cell system.

  Patent Document 1 discloses a fuel cell system that shortens the warm-up time of the fuel cell by utilizing self-heating generated by generating power from the fuel cell itself.

JP 2009-4243

  By the way, depending on the use environment of the vehicle, the fuel cell system mounted on the vehicle may be activated, for example, at a temperature of minus 30 ° C., and in this case, the system currently under development may cause the following inconveniences. The inventors found the sex.

  In the system currently under development, a pressure regulating valve for adjusting the pressure of the cathode gas supplied to the fuel cell is provided in the cathode gas discharge passage, and a part of the cooling water for cooling the fuel cell is used for this pressure regulating valve. And warm up.

  In such a system, when the warm-up of the fuel cell is started, the amount of generated water increases with power generation. When the amount of generated water exceeds the amount of water retained by the electrolyte membrane, the generated water overflowing from the electrolyte membrane is discharged together with the cathode gas into the cathode gas discharge passage. At this time, if the pressure regulating valve provided in the cathode gas discharge passage is still at a temperature of 0 ° C. or less, the generated water flowing into the cathode gas discharge passage is frozen by the pressure regulating valve, and there is a concern that the pressure regulating valve cannot be controlled. .

  The above problem is likely to occur particularly in a situation where power generation from the fuel cell to the drive motor is permitted and the fuel cell generates a large amount of power. In such a situation, since the amount of power generated by the fuel cell increases, warm-up is promoted. On the other hand, the amount of generated water exceeds the amount of water retained in the electrolyte membrane at an early stage. The time to reach is shortened. For this reason, before the temperature of a pressure regulation valve exceeds 0 degreeC, produced | generated water may flow into a discharge channel and a pressure regulation valve may freeze.

  The present invention has been made paying attention to such problems, and an object of the present invention is to provide a fuel cell system that prevents freezing of components provided in the discharge passage of the fuel cell at the time of starting below zero.

  The present invention solves the above problems by the following means.

  The fuel cell system according to the present invention supplies anode gas and cathode gas to the fuel cell and generates power according to the load. The fuel cell system includes a component that is provided in a discharge passage through which any gas discharged from the fuel cell passes, and that controls the state of the fuel cell. The fuel cell system branches from a cooling water passage for cooling the fuel cell, passes through the component, and a branch passage for warming up the component by cooling water flowing through the cooling water passage, and to the fuel cell And a load adjusting unit that adjusts the load based on the required power. Further, when the temperature of the component is lower than the freezing point temperature during the warm-up of the fuel cell, the fuel cell system adjusts the load based on the amount of generated water accompanying power generation or the temperature difference between the component and the fuel cell. And a limiting unit that limits a load adjusted by the unit.

  First, during the warm-up of the fuel cell, when the generated power supplied to the load is large, the amount of generated heat increases and a large amount of generated water is generated due to power generation. Exceed. As a result, the warm-up time of the parts provided in the discharge passage is shortened, so that there is a possibility that the generated water is discharged into the discharge passage in a state where the temperature of the parts is lower than 0 ° C. and the parts are frozen.

  According to the aspect of the present invention, when the component provided in the discharge passage is lower than the freezing point temperature during warm-up, at least one of the amount of water generated in the fuel cell or the temperature difference between the fuel cell and the component is monitored. For this reason, it is possible to appropriately grasp the situation in which the amount of generated water exceeds the water retention amount of the electrolyte membrane at an early stage, and the generated water flows into the discharge passage and the components freeze before the components rise to the freezing point temperature.

  In such a situation, it is possible to adjust the amount of generated water increased or the amount of heat released to the parts by cooling water by limiting the amount of power generated to the load such as the auxiliary equipment and drive motor of the fuel cell system. The above inconvenience can be suppressed. That is, it is possible to prevent freezing of components provided in the discharge passage when the fuel cell is started below zero.

  Embodiments of the present invention and advantages of the present invention will be described in detail below with reference to the accompanying drawings.

FIG. 1 is a diagram showing a configuration of a fuel cell system according to an embodiment of the present invention. FIG. 2 is a block diagram illustrating a functional configuration of the controller. FIG. 3 is a block diagram showing details of the stack power generation limiting unit. FIG. 4 is a map showing the water retention amount of the fuel cell. FIG. 5 is a map showing the upper limit value of the generated current. FIG. 6 is a block diagram showing details of the cooling water pump limiting unit. FIG. 7 is a diagram showing a map showing the lower limit value of the pump speed. FIG. 8 is a block diagram showing details of the heater limiting unit. FIG. 9 is a map showing the lower limit value of the heat generation amount of the heater. FIG. 10 is a diagram illustrating a freeze prevention technique by the warm-up restriction unit.

(First embodiment)
FIG. 1 is a diagram showing a configuration of a fuel cell system 100 according to an embodiment of the present invention.

  The fuel cell system 100 is a power supply system that supplies fuel gas necessary for power generation from the outside to the fuel cell and generates power according to a load. In the present embodiment, electric power is supplied to a drive motor that drives the vehicle.

  The fuel cell system 100 includes a fuel cell stack 110, a cathode gas supply / discharge device 120, an anode gas supply / discharge device 130, a stack cooling device 140, an internal resistance measurement device 150, and a controller 160. The cathode gas supply / discharge device 120, the anode gas supply / discharge device 130, and the stack cooling device 140 are auxiliary devices of the fuel cell system 100.

  The fuel cell stack 110 generates a voltage of several hundred volts (volts), for example. The fuel cell stack 110 is connected to a drive motor and auxiliary equipment. The fuel cell stack 110 is a stack of several hundred fuel cells (battery cells).

  The fuel cell includes an anode electrode (fuel electrode), a cathode electrode (oxidant electrode), and an electrolyte membrane sandwiched between the anode electrode and the cathode electrode. A fuel cell causes an electrochemical reaction (power generation reaction) at an electrolyte membrane using an anode gas (fuel gas) containing hydrogen in an anode electrode and a cathode gas (oxidant gas) containing oxygen in a cathode electrode. The following electrochemical reaction proceeds in both the anode electrode and the cathode electrode.

Anode electrode: 2H ² → 4H ⁺ + 4e− (1)
Cathode electrode: 4H ⁺ + 4e ⁻ + O ² → 2H ² O (2)

  In the fuel cell, an electromotive force is generated and water is generated by the electrochemical reactions (1) and (2). Since the fuel cells are connected in series with each other, in the fuel cell stack 110, the sum of the cell voltages generated in each fuel cell becomes the output voltage.

  The fuel cell stack 110 is supplied with cathode gas from the cathode gas supply / discharge device 120 and supplied with anode gas from the anode gas supply / discharge device 130.

  The cathode gas supply / discharge device 120 is a device that supplies the cathode gas to the fuel cell stack 110 and discharges the cathode off-gas discharged from the fuel cell stack 110 to the atmosphere.

  The cathode gas supply / discharge device 120 includes a cathode gas supply passage 21, a filter 22, a cathode compressor 23, a cathode pressure sensor 24, a cathode gas discharge passage 25, and a cathode pressure regulating valve 26.

  The cathode gas supply passage 21 is a passage for supplying cathode gas to the fuel cell stack 110. One end of the cathode gas supply passage 21 communicates with a passage for taking in oxygen from the outside air, and the other end is connected to the cathode gas inlet hole 121.

  The filter 22 is provided in the cathode gas supply passage 21 and removes foreign matters contained in the cathode gas.

  The cathode compressor 23 is provided in the cathode gas supply passage 21 located downstream of the filter 22. The cathode compressor 23 takes oxygen from the outside air into the cathode gas supply passage 21 and supplies it to the fuel cell stack 110 as cathode gas.

  The cathode pressure sensor 24 is provided in the cathode gas supply passage 21 between the cathode compressor 23 and the cathode gas inlet hole 121. The cathode pressure sensor 24 detects the pressure of the cathode gas. The cathode pressure sensor 24 outputs the detected value to the controller 160. The detected value of the cathode pressure sensor 24 is used, for example, for adjusting the opening of the cathode pressure regulating valve 26.

  The cathode gas discharge passage 25 is a passage for discharging the cathode off gas from the fuel cell stack 110. One end of the cathode gas discharge passage 25 is connected to the cathode gas outlet hole 122 and the other end is opened.

  The cathode pressure regulating valve 26 is provided in the cathode gas discharge passage 25. The cathode pressure regulating valve 26 is controlled to open and close by the controller 160. By this opening / closing control, the pressure of the cathode gas flowing in the passage upstream of the cathode pressure regulating valve 26 is adjusted to a desired pressure.

  The anode gas supply / discharge device 130 is a device that supplies anode gas to the fuel cell stack 110, removes impurities contained in the anode off-gas discharged from the fuel cell stack 110, and circulates the fuel cell stack 110.

  The anode gas supply / discharge device 130 includes a high-pressure tank 31, an anode gas supply passage 32, an anode pressure regulating valve 33, and an anode pressure sensor 34. Further, the anode gas supply / discharge device 130 includes an anode gas circulation passage 35, a gas-liquid separation device 36, a purge valve 37 and a purge valve 38, a circulation pump 39, a discharge passage 351 and a discharge passage 352.

  The high pressure tank 31 stores the anode gas supplied to the fuel cell stack 110 in a high pressure state.

  The anode gas supply passage 32 is a passage for supplying anode gas from the high-pressure tank 31 to the fuel cell stack 110. 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 131.

  The anode pressure regulating valve 33 is provided in the anode gas supply passage 32. The anode pressure regulating valve 33 is controlled to open and close by the controller 160. By this opening / closing control, the pressure of the anode gas supplied from the anode gas supply passage 32 to the fuel cell stack 110 is adjusted.

  The anode pressure sensor 34 is provided in the anode gas supply passage 32 between the anode pressure regulating valve 33 and the anode gas inlet hole 131. The anode pressure sensor 34 detects the pressure of the anode gas. The anode pressure sensor 34 outputs the detected value to the controller 160. The detection value of the anode pressure sensor 34 is used, for example, for adjusting the opening degree of the anode pressure regulating valve 33.

  The anode gas circulation passage 35 is a passage through which the anode gas discharged from the fuel cell stack 110 is circulated to the anode gas supply passage 32. One end of the anode gas circulation passage 35 is connected to the anode gas outlet hole 132 of the fuel cell stack 110, and the other end joins the anode gas supply passage 32 between the anode pressure regulating valve 33 and the anode pressure sensor 34.

  The circulation pump 39 is provided in the anode gas circulation passage 35. The circulation pump 39 circulates the anode gas that has passed through the gas-liquid separator 36 to the fuel cell stack 110.

  The gas-liquid separator 36 is provided in the anode gas circulation passage 35. The anode off gas is discharged from the fuel cell stack 110 to the anode gas circulation passage 35. The anode off-gas contains impurities such as nitrogen, which is an inert gas contained in the cathode gas, and water produced by the power generation reaction, along with excess anode gas that has not been used in the power generation reaction.

  The gas-liquid separator 36 separates impurities such as water and nitrogen gas contained in the anode off gas from the surplus anode gas. The gas-liquid separator 36 is, for example, a buffer tank that temporarily stores the anode off gas, and condenses the water vapor in the anode off gas into liquid water. The anode gas from which impurities have been removed by the gas-liquid separator 36 is supplied again to the fuel cell stack 110 through the anode gas circulation passage 35. In addition, a discharge passage 351 is provided in the lower part of the gas-liquid separator 36.

  The discharge passage 351 is a passage for discharging impurities separated by the gas-liquid separator 36. One end of the discharge passage 351 is connected to the discharge hole of the gas-liquid separator 36, and the other end joins the cathode gas discharge passage 25 downstream of the cathode pressure regulating valve 26.

  The purge valve 37 is provided in the discharge passage 351. The purge valve 37 is controlled to open and close by the controller 160. By this opening / closing control, impurities such as nitrogen gas and liquid water are discharged to the cathode gas discharge passage 25.

  The discharge passage 352 branches from the anode gas circulation passage 35 downstream of the circulation pump 39 and joins the cathode gas discharge passage 25 downstream of the cathode pressure regulating valve 26.

  The purge valve 38 is provided in the discharge passage 352. The purge valve 38 discharges the anode gas to the cathode gas discharge passage 25. The purge valve 38 is controlled to open and close by the controller 160.

  The stack cooling device 140 cools the fuel cell stack 110 using cooling water, which is a refrigerant, and adjusts the fuel cell stack 110 to a temperature suitable for power generation. Further, the stack cooling device 140 heats the cooling water to warm up the fuel cell stack 110 when the fuel cell system 100 is started at zero.

  Furthermore, the stack cooling device 140 also warms up the cathode pressure regulating valve 26, the purge valve 37, and the purge valve 38 using the cooling water. The cathode pressure regulating valve 26, the purge valve 37, and the purge valve 38 are also referred to as “discharge valves” below.

  The stack cooling device 140 includes a cooling water circulation passage 41, a radiator 42, a bypass passage 43, a thermostat 44, a cooling water pump 45, a heater 46, a water temperature sensor 47, a water temperature sensor 48, a branch passage 51, A water temperature sensor 52.

  The cooling water circulation passage 41 is a passage for circulating cooling water through the fuel cell stack 110.

  The radiator 42 is provided in the cooling water circulation passage 41. The radiator 42 cools the cooling water heated by the fuel cell stack 110.

  The bypass passage 43 is a passage that bypasses the radiator 42. One end of the bypass passage 43 is connected to the cooling water circulation passage 41, and the other end is connected to the thermostat 44.

  The thermostat 44 is provided at a portion where the bypass passage 43 joins the cooling water circulation passage 41. The thermostat 44 is an on-off valve. The thermostat 44 automatically opens and closes depending on the temperature of the cooling water flowing inside.

  For example, the thermostat 44 is closed when the temperature of the cooling water flowing inside is lower than a predetermined valve opening temperature, and supplies only the cooling water that has passed through the bypass passage 43 to the fuel cell stack 110. Thereby, relatively high-temperature cooling water flows through the fuel cell stack 110.

  On the other hand, the thermostat 44 begins to open gradually when the temperature of the cooling water flowing inside becomes equal to or higher than the valve opening temperature. The thermostat 44 mixes the cooling water that has passed through the bypass passage 43 and the cooling water that has passed through the radiator 42 and supplies the mixed water to the fuel cell stack 110. Thereby, relatively low-temperature cooling water flows through the fuel cell stack 110.

  The cooling water pump 45 is provided in the cooling water circulation passage 41 between the thermostat 44 and the inlet hole of the fuel cell stack 110. The cooling water pump 45 circulates the cooling water flowing through the fuel cell stack 110. The discharge flow rate of the cooling water pump 45 is controlled by the controller 160.

  The heater 46 is provided in the cooling water circulation passage 41 between the thermostat 44 and the cooling water pump 45. The heater 46 is energized when the fuel cell stack 110 is warmed up to warm the coolant. The amount of heat generated by the heater 46 increases as the power supplied from the fuel cell stack 110 increases. As the heater 46, for example, a PTC heater is used.

  The water temperature sensor 47 is provided in the cooling water circulation passage 41 in the vicinity of the inlet of the fuel cell stack 110. The water temperature sensor 47 detects the temperature of cooling water flowing into the fuel cell stack 110 (hereinafter referred to as “stack inlet water temperature”). The water temperature sensor 47 outputs the detected stack inlet water temperature to the controller 160.

  The water temperature sensor 48 is provided in the cooling water circulation passage 41 near the outlet of the fuel cell stack 110. The water temperature sensor 48 detects the temperature of the cooling water discharged from the fuel cell stack 110 (hereinafter referred to as “stack outlet water temperature”). The water temperature sensor 48 outputs the detected stack outlet temperature to the controller 160.

  The branch passage 51 branches from the cooling water circulation passage 41 downstream of the cooling water pump 45, passes through the cathode pressure regulating valve 26, the purge valve 37 and the purge valve 38, respectively, and enters the cooling water circulation passage 41 upstream of the cooling water pump 45. Join. The cathode pressure regulating valve 26, the purge valve 37, and the purge valve 38 are components used for maintaining a good power generation state of the fuel cell stack 110.

  The reason why the cooling water is allowed to pass through the cathode pressure regulating valve 26 before the purge valve 37 and the purge valve 38 by the branch passage 51 is that the generated water accompanying the power generation is generated on the cathode side. It is easy to be discharged first. Therefore, the cooling water heated by the heater 46 is passed through the cathode pressure regulating valve 26 first, so that the warming-up of the cathode pressure regulating valve 26 can be performed with priority over the purge valve 37 and the purge valve 38.

  The water temperature sensor 52 is provided in the branch passage 51 downstream of the cathode pressure regulating valve 26, the purge valve 37 and the purge valve 38. The water temperature sensor 52 detects the temperature of the cooling water that has passed through the purge valve 38 (hereinafter referred to as “purge valve outlet water temperature”). The water temperature sensor 52 outputs the detected purge valve outlet water temperature to the controller 160.

  The internal resistance measuring device 150 measures the internal resistance (impedance) of the fuel cell stack 110 in order to estimate the wetness of the fuel cell stack 110. The lower the wetness of the electrolyte membrane (the lower the moisture in the electrolyte membrane and the dryr the taste), the higher the impedance, and the higher the wetness of the electrolyte membrane (the more wet the electrolyte membrane and the wetter), the impedance Becomes smaller.

  The internal resistance measurement device 150 measures, for example, the internal resistance (HFR: High Frequency Resistance) of the fuel cell stack 110. The internal resistance measurement device 150 supplies an alternating current to the voltage terminal 119 of the fuel cell stack 110 and detects the amplitude of the voltage generated at the voltage terminal 119 by the alternating current. The internal resistance measuring device 150 calculates the internal resistance value by dividing the detected amplitude by the amplitude of the alternating current. The internal resistance measuring device 150 outputs the internal resistance value to the controller 160.

  The controller 160 includes a microcomputer that includes 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 160 receives the stack inlet water temperature from the water temperature sensor 47, the stack outlet water temperature from the water temperature sensor 48, and the internal resistance value of the fuel cell stack 110 from the internal resistance measurement device 150.

  The controller 160 controls the cathode compressor 23, the cathode pressure regulating valve 26, the anode pressure regulating valve 33, the purge valve 37, and the purge valve 38 based on the measured values such as the stack inlet water temperature, the stack outlet water temperature, and the internal resistance value. Thereby, the flow rates of the cathode gas and the anode gas supplied to the fuel cell stack 110 can be adjusted according to the power generation request, so that the power generation state of the fuel cell stack 110 is well maintained.

  In addition, when the fuel cell system 100 is started up, the controller 160 performs control (hereinafter referred to as “warm-up promotion operation”) for warming up the fuel cell stack 110 to a power generation temperature (for example, 60 ° C.) suitable for power generation.

  In the warm-up promotion operation, the controller 160 electrically connects the fuel cell stack 110 to the auxiliary machine and causes the fuel cell stack 110 to generate electric power necessary for driving the auxiliary machine. Thereby, the fuel cell stack 110 itself is warmed up by the heat generated by the power generation. The electric power generated by the fuel cell stack 110 is supplied to auxiliary machines such as the cathode compressor 23, the cooling water pump 45, and the heater 46.

  Furthermore, the controller 160 sets the rotation speed of the cooling water pump 45 to the upper limit value of the variable range, and sets the heat generation amount of the heater 46 to the upper limit value of the variable range. Thereby, the fuel cell stack 110 is warmed up by the cooling water. In addition, since the generated power consumed by the cooling water pump 45 and the heater 46 increases, the amount of self-heating of the fuel cell stack 110 increases. For this reason, it is possible to shorten the warm-up time from when the fuel cell stack 110 is activated until the warm-up is completed.

  In such a fuel cell system, if the generated water generated by the power generation of the fuel cell exceeds the amount of water that can be retained by the electrolyte membrane, the generated water overflowing from the electrolyte membrane is discharged into the cathode gas discharge passage and the anode gas circulation passage. It is discharged into the discharge passage. At this time, if the cathode pressure regulating valve or the purge valve is still at a temperature of 0 ° C. or less, the discharged generated water is frozen by the cathode pressure regulating valve or the purge valve, and there is a concern that the controller cannot control the cathode pressure regulating valve or the purge valve. The

  The above problem is likely to occur particularly in a situation where power generation from the fuel cell stack to the drive motor is permitted and a large amount of power is generated in the fuel cell stack.

  In such a situation, the amount of heat generated by the fuel cell stack increases, so the warm-up time of the fuel cell stack can be shortened, but the amount of generated water increases due to power generation. It will exceed the amount of water retained. As a result, the time when the generated water reaches the cathode pressure regulating valve or the purge valve is advanced.

  Since the cathode pressure control valve and purge valve are gradually warmed by the cooling water, when the timing of arrival of the generated water is advanced, the generated water reaches the cathode pressure control valve and purge valve in a state where the temperature does not reach 0 ° C. There is concern about freezing.

  Therefore, in the present invention, the temperature of a discharge valve such as a cathode pressure regulating valve or a purge valve provided in the discharge passage and the temperature of the fuel cell stack or the amount of generated water are monitored, and from the fuel cell stack to the load as necessary. Limit the power supplied.

  FIG. 2 is a diagram illustrating a functional configuration of the controller 160 according to the embodiment of the present invention.

  The warm-up control unit 161 controls the cathode gas supply / exhaust device 120, the anode gas supply / exhaust device 130, and the stack cooling device 140 to warm up the fuel cell stack 110 when starting below zero.

  The warm-up control unit 161 uses the pressure sensors 24 and 34, the water temperature sensors 47 and 48, the water temperature sensor 52, and the temperature sensors 261, 371, and 381 to generate the power generation state of the fuel cell stack 110 and the cooling water. Monitor the temperature status of the. The warm-up control unit 161 controls the cathode compressor 23, the cathode pressure regulating valve 26, the anode pressure regulating valve 33, the purge valve 37 and the purge valve 38, the thermostat 44, the cooling water pump 45, and the heater 46.

  The warm-up control unit 161 includes a valve freeze prevention warm-up restriction unit (hereinafter simply referred to as “warm-up restriction unit”) 200, a load adjustment unit 300, and a command unit 400.

  As a countermeasure against freezing of the discharge valve, the warm-up restriction unit 200 is configured to reduce the entire temperature supplied from the fuel cell stack 110 to the load when the temperatures of the cathode pressure regulating valve 26, the purge valve 37, and the purge valve 38 are lower than the freezing point temperature. Limit power generation. Thereby, the increase amount of the generated water per unit time is suppressed. The temperatures of the cathode pressure regulating valve 26, the purge valve 37, and the purge valve 38 are hereinafter referred to as “discharge valve temperature”.

  For example, the warm-up limiting unit 200 uses the fuel cell based on the internal resistance value measured by the internal resistance measuring device 150 and the output current output from the fuel cell stack 110 to a load such as a drive motor and an auxiliary machine. The amount of water produced in the stack 110 is estimated. Then, the warm-up restriction unit 200 sets the upper limit value of the generated current of the fuel cell stack 110 to the load adjustment unit 300 as a limit value for preventing freezing based on the amount of generated water.

  Further, the warm-up restriction unit 200 restricts the power supplied to the cooling water pump 45 and the heater 46 to be high when the discharge valve temperature is lower than the freezing point temperature as a countermeasure against the freezing of the discharge valve.

  For example, the warm-up restriction unit 200 sets the lower limit value of the power supplied to the cooling water pump 45 and the heater 46 as the limit value for preventing freezing based on the temperature difference between the temperature of the fuel cell stack 110 and the discharge valve temperature. The load adjustment unit 300 is set. Thereby, warming-up of the cathode pressure regulating valve 26, the purge valve 37, and the purge valve 38 is promoted.

  In this embodiment, the average value of the stack inlet water temperature and the stack outlet water temperature is used as the temperature of the fuel cell stack 110, and the purge valve outlet water temperature detected by the water temperature sensor 52 is used as the discharge valve temperature.

  Thus, the temperature difference between the stack temperature and the discharge valve temperature can be easily estimated without providing temperature sensors in the fuel cell stack 110, the cathode pressure regulating valve 26, the purge valve 37, and the purge valve 38.

  Further, since the purge valve outlet water temperature is lower than the actual temperature of the cathode pressure regulating valve 26, purge valve 37, and purge valve 38, the purge valve outlet water temperature is used as the discharge valve temperature to implement a countermeasure against freezing on the safe side. Can do.

  Further, the water temperature sensor 52 is provided in the branch passage 51 in the vicinity of the purge valve 38 having the slowest temperature rise among the cathode pressure regulating valve 26, the purge valve 37, and the purge valve 38, and downstream of the purge valve 38. . For this reason, a countermeasure against freezing can be surely implemented until all the discharge valves reach 0 ° C.

  The load adjusting unit 300 supplies power to each of the drive motor, the cathode compressor 23, the cooling water pump 45, and the heater 46 so that the required value of the generated power required for warm-up does not exceed the limit value for freezing countermeasures. Adjust the target value. The required value is a value determined in advance according to the reference characteristic (IV characteristic) of the fuel cell stack 110 at zero.

  The command unit 400 drives the cathode gas supply / discharge device 120, the anode gas supply / discharge device 130, and the stack cooling device 140 based on the target value adjusted by the load adjustment unit 300.

  Next, a detailed configuration of the warm-up control unit 161 will be described with reference to FIGS. 3 to 5. 3 to 5 show configurations for limiting the power generation current of the fuel cell stack 110, the number of revolutions of the cooling water pump 45, and the amount of heat generated by the heater 46, respectively.

  FIG. 3 is a functional block diagram showing details of the stack power generation limiting unit 201 that constitutes the warm-up limiting unit 200. In FIG. 3, in addition to the stack power generation limiting unit 201, a target current setting unit 301 and a warm-up request current calculation unit 310 that configure the load adjustment unit 300 are shown.

  When the discharge valve temperature is lower than the freezing point temperature, the stack power generation limiting unit 201 calculates the upper limit value of the power generation current of the fuel cell stack 110 to prevent the discharge valve from freezing.

  The stack power generation limiting unit 201 acquires the purge valve outlet water temperature from the water temperature sensor 52, the stack inlet water temperature from the water temperature sensor 47, and the stack outlet water temperature from the water temperature sensor 48, respectively. The stack power generation limiting unit 201 calculates an average value of the stack inlet water temperature and the stack outlet water temperature as the stack temperature. Further, the stack power generation limiting unit 201 acquires the internal resistance value from the internal resistance measurement device 150.

  Further, the stack power generation limiting unit 201 holds both the internal resistance value and the stack temperature measured when the fuel cell stack 110 was stopped last time. In general, when starting below zero, the correlation between the water retention amount of the fuel cell and the internal resistance value is shifted due to freezing of the fuel cell stack 110, and the measured value may be higher than the actual internal resistance value. is there. For this reason, the estimation error of the water retention amount increases.

  On the other hand, when the fuel cell system 100 is stopped, the stack temperature is normally kept in the vicinity of the temperature suitable for power generation, so it is considered that the deviation in correlation is relatively small. Therefore, by using the stack temperature and the internal resistance value at the time of the previous stop, it is possible to increase the estimation accuracy of the water retention amount at the start.

  The stack power generation restriction unit 201 includes a generated water amount estimation unit 210, an upper limit current calculation unit 221, a restriction release information holding unit 228, and a restriction switching unit 231.

  The generated water amount estimation unit 210 adds the water retention amount at the time of starting the electrolyte membrane and the power generation generated water amount accompanying power generation, and estimates the total generated water amount of the entire electrolyte membrane.

  The generated water amount estimation unit 210 includes a startup water retention amount calculation unit 211, a power generation generated water amount calculation unit 212, a calculation cycle multiplication unit 213, a generated water amount integration unit 214, and a generated water amount holding unit 215.

  When the ignition key of the vehicle is set to ON and the fuel cell system 100 receives a start command, the start-time water retention amount calculation unit 211 is included in the electrolyte membrane based on the stack temperature and the internal resistance value at the previous stop. The amount of generated water, that is, the amount of water retained at startup is calculated.

  In the present embodiment, a water retention amount map indicating the relationship between the internal resistance value of the fuel cell stack 110 and the water retention amount is stored in advance in the startup water retention amount calculation unit 211 for each stack temperature of the fuel cell stack 110. . The water retention amount map will be described later with reference to FIG.

  Upon receipt of the start command, the startup water retention amount calculation unit 211 refers to the water retention amount map shown in FIG. 4 and maintains the generated water amount with the water retention amount specified by the stack temperature and the internal resistance value at the previous stop. This is recorded in section 215 as the initial value of the amount of produced water.

  In addition, instead of the water retention amount map shown in FIG. 4, the correction data for correcting the internal resistance value according to the stack temperature and the water retention amount data indicating the relationship between the internal resistance value and the water retention amount are separately started. It may be recorded in the water retention amount calculation unit 211. The startup water retention amount calculation unit 211 corrects the internal resistance value at the previous stop with reference to the correction data at startup, and acquires the water retention amount at the previous stop from the water retention amount data based on the corrected internal resistance value.

  Based on the power generation state of the fuel cell stack 110, the power generation water amount calculation unit 212 calculates the power generation water generation amount per unit time.

  In the present embodiment, the power generation generated water amount calculation unit 212 acquires the output current of the fuel cell stack 110, for example, every calculation cycle of 100 ms (milliseconds). As the output current of the fuel cell stack 110, for example, a detection value detected by a current sensor provided in the fuel cell stack 110 may be used, or a previously set target value of the generated current may be used. .

  As shown in the following equation, the power generation generated water amount calculation unit 212 includes an output current I [A], a Faraday constant F [C / mol], the number n of electrons generated (consumed) per mole of the reactant, and a battery cell. The power generation generated water amount Wv [g / sec] is calculated from the number Nc [cell] and the molecular weight Mw [g / mol] of water.

  The Faraday constant F [C / mol], the number n of electrons, the number Nc [cell] of battery cells, and the molecular weight Mw [g / mol] of water are stored in advance in the power generation generated water amount calculation unit 212. .

  The power generation generated water amount calculation unit 212 outputs the power generation generated water amount Wv per unit time to the calculation cycle multiplication unit 213.

  The calculation cycle multiplying unit 213 multiplies the power generation generated water amount Wv by the time Δt of the calculation cycle, and calculates the power generation generated water amount generated during the calculation cycle to the generated water amount integrating unit 214.

  The generated water amount integrating unit 214 calculates the integrated generated water amount by adding the generated power amount from the calculation cycle multiplying unit 213 to the generated water amount held in the generated water amount holding unit 215. Further, the integrated water generation amount is supplied to the upper limit current calculation unit 221 and recorded in the generation water amount holding unit 215.

  The generated water amount holding unit 215 holds the previous calculation result by the generated water amount integrating unit 112 for each calculation cycle. That is, the generated water amount holding unit 215 holds the accumulated generated water amount one cycle before.

  Even in a method other than the above, for example, the start-time water retention amount calculation unit 211 refers to the water retention amount map shown in FIG. 4 and integrates the water retention amount specified by the stack temperature and the internal resistance value acquired for each calculation period Δt. The amount of generated water may be calculated.

  The upper limit current calculation unit 221 calculates a limit value that limits the generated current of the fuel cell stack 110 in order to prevent the discharge valve from freezing. Specifically, the upper limit current calculation unit 221 calculates the upper limit value of the generated current based on the accumulated amount of generated water from the amount of generated water accumulation unit 214 and the stack outlet water temperature detected by the water temperature sensor 48.

  The upper limit current calculation unit 221 stores in advance an upper limit current map indicating the upper limit value of the generated current in accordance with the stack outlet water temperature for each accumulated water amount. Details of the upper limit current map will be described later with reference to FIG.

  The upper limit current calculation unit 221 sets the upper limit value of the generated current to be smaller because the amount of water retained by the electrolyte membrane decreases as the integrated amount of generated water increases. Thereby, since the amount of generated water per unit time accompanying power generation decreases, the time until the generated water overflows from the electrolyte membrane can be delayed.

  Furthermore, the upper limit current calculation unit 221 sets the upper limit value of the generated current to be smaller because the accumulated water amount increases as the stack outlet water temperature increases. This also reduces the amount of water produced per unit time and delays the time it takes for the produced water to overflow from the electrolyte membrane.

  The upper limit current calculation unit 221 outputs the upper limit value of the generated current specified by the accumulated water amount and the stack outlet water temperature to the limit switching unit 231 with reference to the upper limit current map shown in FIG.

  The restriction release information holding unit 228 holds a release value for releasing the restriction of the generated current. As the release value, a value that is always larger than the value output from the warm-up request current calculation unit 310 is set. For example, the release value is set to infinity.

  The limit switching unit 231 sets the upper limit value of the generated current output from the upper limit current calculation unit 221 in the target current setting unit 301 based on the purge valve outlet water temperature detected by the water temperature sensor 52, that is, the discharge valve temperature.

  When the purge valve outlet water temperature is 0 ° C. (or the freezing point temperature) or less, the limit switching unit 231 outputs the upper limit value of the generated current from the upper limit current calculation unit 221 to the target current setting unit 301. On the other hand, when the purge valve outlet water temperature is higher than 0 ° C., the restriction switching unit 231 switches the output value to the release value held in the restriction release information holding unit 228.

  The warm-up required current calculation unit 310 outputs a required value of the generated current necessary for operating the drive motor to the target current setting unit 301 based on the required power for the fuel cell stack 110 required for warm-up.

  The target current setting unit 301 sets the smaller value of the request value from the warm-up request current calculation unit 310 and the limit value output from the limit switching unit 231 as the target current in the command unit 400.

  When the purge valve outlet water temperature is lower than 0 ° C., the target current setting unit 301 selects the smaller value between the upper limit value of the generated current from the limit switching unit 231 and the requested value, and the selected value Is output to the command unit 400.

  That is, the target current setting unit 301 limits the target current of the fuel cell stack 110 so as not to exceed the upper limit value calculated by the upper limit current calculation unit 221 in a temperature environment where the purge valve outlet water temperature is lower than 0 ° C.

  On the other hand, when the discharge valve temperature is 0 ° C. or higher, the target current setting unit 301 selects a request value smaller than the release value output from the limit switching unit 231 and sets the request value of the generated current to the command unit 400. Output to. That is, in the temperature environment where the discharge valve temperature is higher than 0 ° C., the restriction on the target current is released.

  As described above, when the discharge valve temperature is lower than 0 ° C., the stack power generation limiting unit 201 sets the upper limit value of the generated current to be small according to the integrated amount of generated water.

  In this way, until the discharge valve temperature exceeds 0 ° C., the amount of generated water per unit time is reduced according to the integrated amount of generated water, so that the time when the generated water is discharged from the fuel cell stack 110 is It can be delayed until it exceeds 0 ° C. Therefore, freezing of components such as the cathode pressure regulating valve 26, the purge valve 37, and the purge valve 38 can be prevented.

  FIG. 4 is a diagram illustrating a water retention amount map held in the startup water retention amount calculation unit 211. In FIG. 4, the horizontal axis represents the internal resistance value of the fuel cell stack 110, and the vertical axis represents the water retention amount of the fuel cell stack 110.

  In the water retention amount map, the internal resistance value and the water retention amount of the fuel cell stack 110 are associated with each other for each stack outlet water temperature.

  In the water retention amount map, the water retention amount decreases as the internal resistance value increases. Further, at the same internal resistance value, the lower the stack outlet water temperature, the larger the water retention amount. When the temperature of the fuel cell stack 110 is lowered, the measured value of the internal resistance measuring device 150 is estimated to be larger than the original internal resistance due to freezing. As a countermeasure, the water retention amount map shows the relationship between the internal resistance value and the water retention amount for each stack outlet water temperature.

  FIG. 5 is a diagram illustrating an upper limit current map held in the upper limit current calculation unit 221. In FIG. 5, the horizontal axis represents the stack outlet water temperature T of the fuel cell stack 110, and the vertical axis represents the upper limit value of the generated current. The maximum value MAX is a generated current necessary for warm-up, and the minimum value MIN is determined to prevent system abnormalities such as dryout.

  In the upper limit current map, the stack outlet water temperature and the upper limit value of the generated current are associated with each other for each generated water amount W of the fuel cell stack 110. The upper limit value of the generated current is set based on experimental data, for example. Here, the relationship between the water tack outlet water temperature and the upper limit value of the generated current is shown for each of the generated water amounts W1 to W3.

  In the upper limit current map, the higher the stack outlet temperature, the smaller the upper limit value of the generated current. In addition, at the same stack outlet water temperature, the higher the amount of generated water, the lower the upper limit value of the generated current.

  Next, an example will be described in which the lower limit value of the rotation speed of the cooling water pump 45 is set high to prevent the discharge valve from freezing.

  FIG. 6 is a functional block diagram showing details of the cooling water pump limiting unit 202 that constitutes the warm-up limiting unit 200. In FIG. 6, in addition to the cooling water pump limiting unit 202, a target rotation speed setting unit 302 and a warm-up required rotation speed calculation unit 320 that constitute the load adjustment unit 300 are shown.

  The cooling water pump limiting unit 202 calculates a lower limit value of the rotation speed of the cooling water pump 45 in order to prevent the discharge valve from freezing.

  The cooling water pump limiting unit 202 acquires the stack outlet water temperature from the water temperature sensor 48, and acquires the purge valve outlet water temperature from the water temperature sensor 52 as the discharge valve temperature.

  The cooling water pump restriction unit 202 includes a temperature difference calculation unit 216, a lower limit rotation speed calculation unit 222, a restriction release information holding unit 229, and a restriction switching unit 232.

  The temperature difference calculation unit 216 calculates the temperature difference by subtracting the purge valve outlet water temperature from the stack outlet water temperature. The temperature difference calculation unit 216 outputs the calculated temperature difference to the lower limit rotation speed calculation unit 222.

  The lower limit rotation speed calculation unit 222 calculates a lower limit value that limits the rotation speed of the cooling water pump 45 according to the temperature difference between the stack outlet water temperature and the purge valve outlet water temperature.

  In the present embodiment, the pump speed map is stored in advance in the lower limit speed calculator 222. The pump rotation speed map shows the relationship between the temperature difference between the stack outlet water temperature and the purge valve outlet water temperature and the lower limit value of the pump rotation speed for each stack outlet water temperature. The pump speed map will be described later with reference to FIG.

  When obtaining the temperature difference calculated by the temperature difference calculation unit 216, the lower limit rotation number calculation unit 222 refers to the pump rotation number map and calculates the difference between the stack outlet water temperature and the purge valve outlet water temperature and the purge valve outlet water temperature. Calculate the lower limit of the specified pump speed.

  The lower limit rotational speed calculation unit 222 increases the lower limit value of the pump rotational speed because the heat radiation amount from the cooling water to the discharge valve increases as the temperature difference between the stack outlet water temperature and the purge valve outlet water temperature increases.

  As a result, warm-up of the cathode pressure regulating valve 26, the purge valve 37, and the purge valve 38 is promoted, and therefore, the cathode pressure regulating valve 26, the purge valve 37, and the purge valve 38 are discharged before the generated water is discharged from the fuel cell stack 110. It is possible to reach a temperature of 0 ° C.

  Further, the lower limit rotational speed calculation unit 222 increases the heat radiation amount from the cooling water to the cathode pressure regulating valve 26, the purge valve 37, and the purge valve 38 as the stack outlet water temperature increases at the same temperature difference. Increase the lower limit of.

  This also promotes warm-up of the cathode pressure regulating valve 26, the purge valve 37, and the purge valve 38. Therefore, before the generated water is discharged from the fuel cell stack 110, the cathode pressure regulating valve 26, the purge valve 37, and the purge valve. The temperature of 38 can reach 0 ° C.

  The lower limit rotational speed calculation unit 222 limits the lower limit value of the pump rotational speed specified by the temperature difference between the stack temperature and the discharge valve temperature and the stack outlet water temperature with reference to the pump rotational speed map for each calculation cycle. Output to.

  The restriction release information holding unit 229 holds a release value for releasing the restriction on the pump rotation speed. The release value is always set to a value smaller than the value output from the warm-up request rotation speed calculation unit 320. For example, the release value is set to 0 (zero).

  Based on the purge valve outlet water temperature detected by the water temperature sensor 52, that is, the discharge valve temperature, the limit switching unit 232 sets the lower limit value of the pump rotation number output from the lower limit rotation number calculation unit 222 to the target rotation number setting unit 302. Set.

  When the discharge valve temperature is 0 ° C. or lower, the limit switching unit 232 outputs the lower limit value of the pump rotation number from the lower limit rotation number calculation unit 222 to the target rotation number setting unit 302. On the other hand, when the discharge valve temperature is higher than 0 ° C., the limit switching unit 232 switches to the release value held in the limit release information holding unit 229.

  Based on the required power for fuel cell stack 110, warm-up request rotational speed calculation unit 320 outputs a required value for the pump rotational speed necessary to drive cooling water pump 45 to target rotational speed setting unit 302.

  Target revolution number setting unit 302 uses command value 400 as a target revolution number, whichever is smaller between the requested value output from warm-up required revolution number calculation unit 320 and the limit value output from limit switching unit 232. Set to.

  When the purge valve outlet water temperature is lower than 0 ° C., the target rotation number setting unit 302 selects the lower value of the pump rotation number from the limit switching unit 232 and the required value, and selects the selected value. The value is output to the command unit 400. That is, the target rotation speed setting unit 302 sets the target rotation speed of the cooling water pump 45 so that it does not become lower than the lower limit value calculated by the lower limit rotation speed calculation unit 222 in a temperature environment where the discharge valve temperature is lower than 0 ° C. Limit high.

  On the other hand, when the discharge valve temperature is 0 ° C. or higher, the target rotation speed setting unit 302 selects a request value that is larger than the release value output from the limit switching unit 232 and sends the request value to the command unit 400. Output. That is, in the temperature environment where the discharge valve temperature is higher than 0 ° C., the restriction on the cooling water pump 45 is released.

  As described above, when the discharge valve temperature is lower than 0 ° C., the cooling water pump limiting unit 202 reduces the lower limit value of the pump rotation speed in accordance with the temperature difference between the stack outlet water temperature and the purge valve outlet water temperature. For this reason, the rotation speed of the cooling water pump 45 is increased as the heat radiation amount from the cooling water to the discharge valve increases until the discharge valve temperature exceeds 0 ° C.

  Thereby, the time when the purge valve outlet water temperature reaches 0 ° C. can be advanced. Therefore, the warming-up of the cathode pressure regulating valve 26, the purge valve 37, and the purge valve 38 is completed before the generated water is discharged from the fuel cell stack 110, so that these components can be prevented from freezing.

  FIG. 7 is a diagram illustrating a pump rotation speed map held in the lower limit rotation speed calculation unit 222. In FIG. 7, the horizontal axis is the temperature difference ΔT between the stack outlet water temperature and the purge valve outlet water temperature, and the vertical axis is the lower limit value of the rotation speed of the cooling water pump 45.

  In the pump rotation speed map, the temperature difference ΔT and the lower limit value of the pump rotation speed are associated with each other for each stack outlet water temperature T. The lower limit value of the pump speed is set based on experimental data, for example. Here, the relationship between the temperature difference ΔT and the lower limit value of the pump speed is shown for each of the stack outlet water temperatures T1 and T3.

  In the pump rotation speed map, the lower limit value of the pump rotation speed decreases as the temperature difference ΔT increases. In addition, at the same temperature difference ΔT1, the lower limit value of the pump speed increases as the stack outlet water temperature T increases.

  Next, an example will be described in which the lower limit value of the heat generation amount of the heater 46 is restricted to prevent the discharge valve from freezing.

  FIG. 8 is a functional block diagram showing details of the heater restriction unit 203 constituting the warm-up restriction unit 200. In FIG. 8, in addition to the heater restriction unit 203, a target heat generation amount setting unit 303 and a warm-up required heat generation amount calculation unit 330 configuring the load adjustment unit 300 are shown.

  The heater limiting unit 203 calculates a lower limit value of the heat generation amount of the heater 46 in order to prevent the cathode pressure regulating valve 26, the purge valve 37 and the purge valve 38 from freezing.

  The heater restriction unit 203 acquires the stack outlet water temperature and the purge valve outlet water temperature, respectively, similarly to the cooling water pump restriction unit 202 shown in FIG.

  The heater restriction unit 203 includes a temperature difference calculation unit 217, a lower limit calorific value calculation unit 223, a restriction release information holding unit 229, and a restriction switching unit 233.

  The temperature difference calculation unit 217 calculates the temperature difference by subtracting the purge valve outlet water temperature from the stack outlet water temperature. The temperature difference calculation unit 217 outputs the calculated temperature difference to the lower limit calorific value calculation unit 223.

  The lower limit heat generation amount calculation unit 223 calculates a lower limit value for limiting the heat generation amount of the heater 46 according to the temperature difference between the stack outlet water temperature and the purge valve outlet water temperature.

  In the present embodiment, the lower limit heat generation amount calculation unit 223 stores a heater heat generation amount map in advance. The heater heating value map shows the relationship between the temperature difference between the stack outlet water temperature and the purge valve outlet water temperature and the lower limit value of the heater heating value for each stack temperature. The heater heating value map will be described later with reference to FIG.

  When the temperature difference calculated by the temperature difference calculation unit 217 is acquired, the lower limit heat generation amount calculation unit 223 refers to the heater heat generation amount map and specifies the temperature difference between the stack outlet water temperature and the purge valve outlet water temperature and the stack outlet water temperature. The lower limit value of the amount of generated heat is calculated.

  The lower limit heat generation amount calculation unit 223 sets the lower limit value of the heat generation amount larger because the heat release amount from the cooling water to the discharge valve increases as the temperature difference between the stack outlet water temperature and the purge valve outlet water temperature increases.

  As a result, warming-up of the cathode pressure regulating valve 26, the purge valve 37, and the purge valve 38 by the cooling water is promoted. Therefore, before the generated water is discharged from the fuel cell stack 110, the cathode pressure regulating valve 26, the purge valve 37, and The temperature of the purge valve 38 can reach 0 ° C.

  Furthermore, the lower limit heat generation amount calculation unit 223 increases the lower limit value of the heat generation amount of the heater because the heat radiation amount from the cooling water to the discharge valve increases as the stack outlet water temperature increases at the same temperature difference.

  This also promotes warming up of the cathode pressure regulating valve 26, the purge valve 37, and the purge valve 38 by the cooling water, so that the cathode pressure regulating valve 26 and the purge valve 37 are discharged before the generated water is discharged from the fuel cell stack 110. In addition, the temperature of the purge valve 38 can reach 0 ° C.

  The lower limit heat generation amount calculation unit 223 limits the lower limit value of the heat generation amount specified by the temperature difference between the stack outlet water temperature and the purge valve outlet water temperature and the stack outlet water temperature with reference to the heater heat generation amount map for each calculation cycle. To 233.

  The restriction release information holding unit 229 holds a release value for releasing the restriction on the amount of heat generated by the heater 46. The release value is always set to a value smaller than the value output from the warm-up required heat generation amount calculation unit 330. For example, the release value is set to 0 (zero).

  The limit switching unit 233 sets the lower limit value of the heat generation amount output from the lower limit heat generation amount calculation unit 223 in the target heat generation amount setting unit 303 based on the purge valve outlet water temperature detected by the water temperature sensor 52, that is, the discharge valve temperature. To do.

  When the discharge valve temperature is 0 ° C. or lower, the limit switching unit 233 outputs the lower limit value of the heat generation amount from the lower limit heat generation amount calculation unit 223 to the target rotation number setting unit 302. On the other hand, when the discharge valve temperature is higher than 0 ° C., the limit switching unit 232 switches the output value to the release value held in the limit release information holding unit 229.

  The warm-up required heat generation amount calculation unit 330 outputs the required value of the heat generation amount of the heater 46 necessary for heating the cooling water to the target heat generation amount setting unit 303 based on the required power for the fuel cell stack 110.

  The target heat generation amount setting unit 303 uses the smaller value of the request value output from the warm-up required heat generation amount calculation unit 330 and the limit value output from the limit switching unit 233 as the target heat generation amount. Set to.

  When the discharge valve temperature is lower than 0 ° C., the target heat generation amount setting unit 303 selects the lower value of the heater heat generation amount from the limit switching unit 233 and the required value, and selects the selected value. Is output to the command unit 400. That is, the target heat generation amount setting unit 303 restricts the target heat generation amount of the heater 46 to be higher than the lower limit value calculated by the lower limit heat generation amount calculation unit 223 in a temperature environment where the discharge valve temperature is lower than 0 ° C. To do.

  On the other hand, when the discharge valve temperature is 0 ° C. or higher, the target heat generation amount setting unit 303 selects a request value that is larger than the release value output from the limit switching unit 233, and instructs the heater heat generation amount request value. Output to the unit 400. That is, in the temperature environment where the discharge valve temperature is higher than 0 ° C., the restriction on the heater 46 is released.

  As described above, when the discharge valve temperature is lower than 0 ° C., the heater limiting unit 203 sets the lower limit value of the heater heat generation amount to be small according to the temperature difference between the stack outlet water temperature and the purge valve outlet water temperature. Therefore, until the discharge valve temperature exceeds 0 ° C., the heat generation amount of the heater 46 is increased as the heat release amount from the cooling water to the discharge valve increases.

  Thereby, the time when the purge valve outlet water temperature reaches 0 ° C. can be advanced. Therefore, the warming-up of the cathode pressure regulating valve 26, the purge valve 37, and the purge valve 38 is completed before the generated water is discharged from the fuel cell stack 110, so that these components can be prevented from freezing.

  FIG. 9 is a diagram showing a heater heat generation amount map held in the lower limit heat generation amount calculation unit 223. In FIG. 9, the horizontal axis is the temperature difference ΔT between the stack outlet water temperature and the purge valve outlet water temperature, and the vertical axis is the lower limit value of the heat generation amount of the heater 46.

  In the heater heat generation amount map, for each stack outlet water temperature T, the temperature difference ΔT and the lower limit value of the heater heat generation amount are associated with each other. The lower limit value of the heating value of the heater is set based on experimental data, for example. Here, the relationship between the temperature difference ΔT and the lower limit value of the heating value of the heater is shown for each of the stack outlet water temperatures T2 and T3.

  In the heater heat value map, the lower the heater heat value, the smaller the stack outlet temperature becomes. In addition, at the same temperature difference ΔT2, the lower limit value of the heater heat generation amount increases as the stack outlet water temperature T increases.

  Further, in the heater heat generation amount map of the present embodiment, the lower limit value is set so as to increase the pump rotation speed before the heater heat generation amount. Thereby, the power consumption of the heater 46 is suppressed.

  Next, an example of restricting the warm-up promotion operation by the warm-up restriction unit 200 will be described with reference to the drawings.

  FIG. 10 is a time chart showing a state change of the fuel cell system 100 by the warm-up restriction unit 200.

  Fig.10 (a) is a figure which shows the change of stack exit water temperature. FIG.10 (b) is a figure which shows the change of integrated production | generation water amount. FIG. 10C is a diagram showing a change in the rotational speed of the cooling water pump 45. FIG. 10D is a diagram showing a change in the amount of heat generated by the heater 46. FIG. 10E is a diagram showing a change in the generated current of the fuel cell stack 110.

  10A to 10E, the change in the state of the fuel cell system 100 is indicated by a solid line, and the change in the limit value set by the warm-up restriction unit 200 is indicated by a one-dot chain line. The horizontal axis is a common time axis.

  At time t0, as shown in FIG. 10A, the fuel cell system 100 is started under zero, and both the stack outlet water temperature and the purge valve outlet water temperature are 0 ° C. or less.

  When the fuel cell system 100 is activated, the stack power generation limiting unit 201 refers to the water retention amount map shown in FIG. 4 and sets the startup water retention amount W0 specified by the internal resistance value at the previous stop and the stack outlet water temperature. get.

  Further, the cooling water pump limiting unit 202 refers to the pump rotation speed limit map shown in FIG. 7, and the pump rotation speed specified by the temperature difference ΔT between the stack outlet water temperature and the purge valve outlet water temperature and the stack outlet water temperature T. Set the lower limit of. The heater restriction unit 203 sets a lower limit value of the heater heat generation amount specified by the temperature difference ΔT and the stack outlet water temperature T with reference to the heater heat generation amount restriction map shown in FIG.

  Further, the stack power generation limiting unit 201 calculates the integrated generated water amount W by adding the generated water amount based on the stack output current and adding the integrated generated water amount to the start-up water retention amount W0 for each calculation cycle. Then, the stack power generation limiting unit 201 refers to the upper limit current map shown in FIG. 5 and sets the upper limit value of the power generation current specified by the accumulated water amount W and the stack outlet water temperature T.

  In order to warm up the fuel cell stack 110 using the cooling water, the warm-up control unit 161 sets the rotation speed of the cooling water pump 45 to the upper limit value MAX of the variable range as shown in FIG. After that, as shown in FIG. 10D, the heat generation amount of the heater 46 is set to the upper limit value MAX of the variable range.

  Further, in order to warm up using the self-heating generated by the power generation of the fuel cell stack 110, the warm-up control unit 161 connects auxiliary equipment such as the cooling water pump 45 and the heater 46 to the fuel cell stack 110, and The fuel cell stack 110 is made to generate electric power necessary for driving the battery.

  Due to self-heating of the fuel cell stack 110 and heating of the cooling water by the heater 46, the stack outlet water temperature gradually rises as shown in FIG. In contrast, the purge valve outlet water temperature is only slightly increased. Further, as shown in FIG. 10B, the amount of generated water gradually increases as the fuel cell stack 110 generates power.

  At time t1, since the stack outlet water temperature rises to 0 ° C., the drive motor is connected to the fuel cell stack 110, and the power generation by the fuel cell stack 110 to the drive motor is permitted. As a result, as shown in FIG. 10 (e), the generated current of the fuel cell stack 110 is set high up to the required value required for traveling of the vehicle.

  On the other hand, for the cooling water pump 45 and the heater 46, since the cooling water is also warmed by the residual heat of the fuel cell stack 110, the set values are gradually lowered as shown in FIGS. 10 (c) and 10 (d). Thereby, unnecessary power consumption by the auxiliary machine can be suppressed, and power supply to the drive motor can be prioritized. In particular, for the heater 46, the heating effect of the cooling water on the fuel cell stack 110 gradually decreases as the warm-up progresses. Therefore, the power consumption can be efficiently reduced by gradually lowering the lower limit value.

  When time t2 elapses, the temperature difference ΔT between the stack outlet water temperature and the purge valve outlet water temperature increases as shown in FIG. 10A, so that the cooling water pump limiting unit 202 is operated as shown in FIG. Increase the lower limit of the pump speed.

  Specifically, the lower limit value of the pump rotational speed specified by the temperature difference ΔT1 and the stack outlet water temperature T1 based on the pump rotational speed map shown in FIG. 7 is 0 (zero) as the stack outlet water temperature T1 increases. Is set to a larger value. When the lower limit value of the pump rotation speed becomes larger than the minimum rotation speed necessary for circulating the cooling water, the cooling water pump limiting unit 202 sets the target rotation speed of the cooling water pump 45 in the setting range according to the pump rotation speed map. Is increased to the upper limit value MAX.

  As a result, the amount of heat released to the discharge valve due to the circulation of the cooling water increases, so that the rate of temperature rise of the purge valve outlet water temperature increases as shown in FIG.

  Since the temperature difference ΔT1 does not decrease as shown in FIG. 10A even after the time t3 has elapsed, the heater limiting unit 203 increases the lower limit value of the heater heating value as shown in FIG. 10D.

  Specifically, the lower limit value of the pump rotation speed specified by the temperature difference ΔT2 and the stack outlet water temperature T2 is larger than zero as the stack outlet water temperature T2 increases according to the heater heat generation amount map shown in FIG. Set to a value. When the lower limit value of the heater heating value map becomes larger than the set value of the heater 46, the cooling water pump limiting unit 202 increases the target heating value of the heater 46 to the upper limit value MAX of the setting range according to the heater heating value map.

  As a result, the amount of heat released to the discharge valve due to heating of the cooling water is further increased, so that the temperature increase rate of the discharge valve temperature is further increased.

  When the time t4 elapses, the accumulated generated water amount W3 approaches the retained water amount that can be retained by the electrolyte membrane, so that the stack power generation limiting unit 201 sets the upper limit value of the generated current to the stack heating rate as shown in FIG. Is lower than the limit value MAX.

  Specifically, according to the generated current limit map shown in FIG. 4, the upper limit value of the generated current specified by the stack outlet water temperature T3 and the accumulated generated water amount W3 increases as the accumulated generated water amount rises above W3. It is set to a value smaller than the speed limit value MAX. When the upper limit value of the power generation current limit map becomes smaller than the power generation current of the fuel cell stack 110, the stack power generation limit unit 201 sets the target current of the fuel cell stack 110 to the minimum required for warming up according to the power generation current limit map. The current value is limited.

  As a result, the amount of increase in the cumulative amount of generated water is reduced as shown in FIG. 5B, so that the time when the generated water overflowing from the electrolyte membrane is discharged from the fuel cell stack 110 can be delayed.

  After that, at time t5, the purge valve outlet water temperature reaches 0 ° C. as indicated by the broken line in FIG. 10A, so that the cooling water pump limiting unit 202, the heater limiting unit 203, and the stack power generation limiting unit 201 are c) to the limit value for preventing freezing as shown in FIG.

  As a result, the generated water is discharged from the fuel cell stack 110 after the discharge valve temperature has been raised to 0 ° C., so that the discharge valve can be prevented from freezing due to the generated water.

  In the fuel cell system 100 of the present invention, components of the cathode pressure regulating valve 26, the purge valve 37 and the purge valve 38 are provided to control the state of the fuel cell stack 110. Specifically, the cathode pressure regulating valve 26 is provided in the cathode gas discharge passage 25 that discharges the cathode gas from the fuel cell stack 110, and the purge valve 37 is liquid water separated from the anode gas by the gas-liquid separator 36. Are provided in a discharge passage 351 for discharging impurities such as. Further, the purge valve 38 is provided in the discharge passage 352 for discharging the anode gas from which impurities have been removed by the gas-liquid separator 36.

  Further, the fuel cell system 100 is provided with a branch passage 51 that branches from the cooling water circulation passage 41 and passes through the cathode pressure regulating valve 26, the purge valve 37, and the purge valve 38. Thereby, the discharge valve of the cathode pressure regulating valve 26, the purge valve 37 and the purge valve 38 is warmed up by the cooling water flowing through the branch passage 51. Based on the required power to the fuel cell stack 110 required for warm-up, the load adjustment unit 300 adjusts the generated power supplied to loads such as the cooling water pump 45, the heater 46, and the drive motor.

  For this reason, during the warming-up of the fuel cell stack 110, when the amount of power generation required for the fuel cell stack 110 is large, the amount of generated water is increased and the amount of generated water is generated at an early stage. Exceeds water retention. As a result, the cathode pressure regulating valve 26, the purge valve 37, and the purge valve 38 are not warmed up in time, and the generated water is discharged from the fuel cell stack 110 while the discharge valve temperature is still 0 ° C. or lower. In this case, the cathode pressure regulating valve 26, the purge valve 37, and the purge valve 38 are frozen by the generated water.

  According to the aspect of the present invention, the warm-up limiting unit 200 supplies the load based on the amount of water generated during power generation when the discharge valve temperature is lower than the freezing point temperature while the fuel cell stack 110 is warming up. Limit the power generated.

  As described above, since the amount of generated water and the discharge valve temperature of the fuel cell stack 110 are monitored, the situation where the generated water is discharged from the fuel cell stack 110 before the discharge valve temperature rises to 0 ° C. is appropriate. Can grasp.

  In such a situation, the warm-up restriction unit 200 can suppress the amount of generated water by restricting the load based on the power generation request for warm-up, so that the parts provided in the discharge passage are prevented from freezing. can do.

  Specifically, when the warm-up restriction unit 200 determines that the cathode pressure regulating valve 26, the purge valve 37, and the purge valve 38 are lower than the freezing point temperature, the warm-up restriction unit 200 determines the generated current of the fuel cell stack 110 based on the accumulated water amount. Set the upper limit.

  As a result, the amount of generated water per unit time associated with power generation is reduced, so the timing at which the generated water is discharged from the fuel cell stack 110 can be delayed. For this reason, the time for warming up the cathode pressure regulating valve 26, the purge valve 37, and the purge valve 38 with the cooling water flowing through the branch passage 51 is lengthened. Can be discharged from.

  In the present embodiment, the warm-up restriction unit 200 decreases the upper limit value of the generated current because the amount of generated water that can be retained by the electrolyte membrane decreases as the integrated amount of generated water increases.

  As a result, when the accumulated water volume is small, the upper limit value is increased to promote warm-up by power generation, and as the accumulated water volume approaches the upper limit of the water retention volume, the upper limit value is lowered and the time when the produced water overflows from the electrolyte membrane. Can be delayed. Therefore, warm-up can be completed quickly while suppressing freezing of the discharge valve.

  Further, in the present embodiment, the warm-up limiting unit 200 decreases the upper limit value of the generated current because the heat generation amount increases and the amount of generated water increases per unit time as the stack temperature of the fuel cell stack 110 increases.

  Accordingly, when the stack temperature is low, the upper limit value is increased to promote warm-up by power generation, and when the stack temperature is increased, the upper limit value is decreased to delay the time when the generated water overflows from the electrolyte membrane. Therefore, warm-up can be completed quickly while suppressing freezing of the discharge valve in accordance with the increase in the amount of generated water.

  In the present embodiment, the warm-up restriction unit 200 includes a generated water amount estimation unit 210 and an upper limit current calculation unit 221. The generated water amount estimation unit 210 estimates the generated water amount based on the water retention amount of the fuel cell stack 110 and the generated current, and the upper limit current calculation unit 221 refers to the upper limit current map shown in FIG. And the upper limit value of the generated current associated with the stack temperature is calculated.

  By using the upper limit current map, the process of calculating the upper limit value of the generated current can be made quickly and easily.

  In the present embodiment, the generated water amount estimation unit 210 includes a startup water retention amount calculation unit 211 and a generated water amount integration unit 214. The startup water retention amount calculation unit 211 calculates a water retention amount based on the internal resistance value at the time of startup of the fuel cell stack 110, and the generated water amount integration unit 214 integrates the generated power generation water amount based on the generated current for each calculation cycle, The total amount of generated water is calculated by adding the amount of generated power to the amount of water retained at startup.

  Thereby, compared with the process which calculates the integrated production | generation water amount based on an internal resistance value sequentially, a calculation process can be reduced.

  Further, in the present embodiment, the warm-up restriction unit 200 restricts the power supplied to auxiliary equipment such as the cooling water pump 45 and the heater 46 to be high based on the temperature difference between the stack temperature and the discharge valve temperature. Thereby, the discharge valve temperature can reach 0 ° C. at an early stage.

  For example, the warm-up restriction unit 200 increases the lower limit value of the power supplied to the cooling water pump 45 higher than the target power based on the required power required for warm-up as the temperature difference increases.

  Specifically, when it is determined that the temperature difference is greater than a predetermined threshold, warm-up restriction unit 200 makes the lower limit value of the rotation speed of cooling water pump 45 higher than the target rotation speed. Note that the power supplied from the fuel cell stack 110 to the coolant pump 45 increases as the pump speed increases. The target rotation speed is set based on the required power required for warming up.

  As a result, when the temperature difference is small, the amount of heat released to the discharge valve by the cooling water is small, so that the upper limit value can be lowered to reduce wasteful power consumption by the cooling water pump 45. On the other hand, when the temperature difference is large, the amount of heat released to the discharge valve by the cooling water increases, so that the upper limit value can be increased to promote warm-up.

  Thus, since the circulation of the cooling water is improved in a situation where the amount of heat released to the discharge valve by the cooling water is relatively high, the discharge valve can be warmed up efficiently and quickly.

  In addition, the warm-up restriction unit 200 increases the lower limit value of the power supplied to the heater 46 higher than the target power based on the required power required for warm-up as the temperature difference between the stack temperature and the discharge valve temperature increases.

  For example, when the warm-up restriction unit 200 determines that the temperature difference is larger than a predetermined threshold value, the warm-up restriction unit 200 makes the heat generation amount of the heater 46 higher than the target heat generation amount. Note that as the amount of heat generated by the heater 46 increases, the power supplied to the heater 46 increases. Further, the target heat generation amount is set based on the required power required for warming up.

  As a result, when the temperature difference is small, the amount of heat released to the discharge valve by the cooling water is small, so the upper limit value can be lowered to reduce wasteful power consumption by the heater 46. On the other hand, when the temperature difference is large, the amount of heat released to the discharge valve by the cooling water increases, so that the upper limit value can be increased to promote warm-up. Therefore, the discharge valve can be warmed up efficiently and quickly.

  In the present embodiment, the warm-up limiting unit 200 increases the power supplied to the heater 46 to the upper limit value of the setting range after the power supplied to the cooling water pump 45 is higher than the target power.

  As described above, the power consumption by the heater 46 can be suppressed by increasing the power supplied to the cooling water pump 45 before restricting the power supplied to the heater 46 high.

  In the present embodiment, when the warm-up restriction unit 200 determines that the stack temperature has risen to the freezing point temperature, it returns the power supplied to the auxiliary machine to the target power. As a result, wasteful power consumption by the cooling water pump 45 and the heater 46 can be suppressed during warm-up, thereby improving fuel efficiency.

  As described above, according to the present invention, by limiting the amount of generated power supplied to loads such as auxiliary machines and drive motors of the fuel cell system 100, the amount of generated water increased, the amount of heat released to components by cooling water, etc. Can be adjusted. Therefore, it is possible to prevent the parts provided in the discharge passage from freezing when the fuel cell is started below zero.

  The embodiment of the present invention has been described above. However, the above embodiment only shows a part of application examples of the present invention, and the technical scope of the present invention is limited to the specific configuration of the above embodiment. Absent.

  For example, although the purge valve outlet water temperature is used as the discharge valve temperature in this embodiment, a temperature sensor is provided in any of the cathode pressure regulating valve 26, the purge valve 37, and the purge valve 38, and the detected value is used as the discharge valve temperature. Also good.

  In addition, the said embodiment can be combined suitably.

100 Fuel Cell System 110 Fuel Cell Stack (Fuel Cell)
45 Cooling water pump (auxiliary machine)
46 Heater (auxiliary machine)
48 Water temperature sensor (fuel cell temperature)
161 Warm-up control unit 200 Warm-up control unit 210 Generated water amount estimation unit (calculation unit)
221 Upper limit current calculation unit (holding unit, upper limit value calculation unit)
300 Load adjuster

Claims (11)

A fuel cell system for supplying anode gas and cathode gas to a fuel cell and generating electric power according to a load,
A part provided in a discharge passage for discharging any gas from the fuel cell, for controlling the state of the fuel cell;
A branch passage that branches from a cooling water passage through which cooling water for cooling the fuel cell passes, passes through the component, and warms up the component with the cooling water;
A load adjusting unit that adjusts the load based on the required power to the fuel cell;
During the warm-up of the fuel cell, when the temperature of the component is lower than the freezing point temperature, the load adjustment unit adjusts the amount of water generated due to power generation or the temperature difference between the component and the fuel cell. A fuel cell system including a limiting unit for setting a limit value; The fuel cell system according to claim 1, wherein
When the limiting unit determines that the part is lower than the freezing point temperature, the upper limit value of the generated power supplied to the load is calculated as the limit value based on the amount of generated water.
Fuel cell system. The fuel cell system according to claim 2, wherein
The limiting unit decreases the upper limit value of the generated power as the amount of generated water in the fuel cell increases.
Fuel cell system. In the fuel cell system according to claim 2 or 3,
The limiting unit decreases the upper limit value of the generated power as the temperature of the fuel cell increases.
Fuel cell system. In the fuel cell system according to any one of claims 1 to 4,
The restriction unit is
A holding unit that holds the temperature of the fuel cell and the upper limit value of the generated current of the fuel cell in association with each other for each amount of water generated in the fuel cell;
A calculation unit that calculates a generated water amount based on a water retention amount and a generated current of the fuel cell;
An upper limit value calculation unit that calculates an upper limit value of the generated current held in the holding unit based on the amount of generated water calculated by the calculation unit and the outlet water temperature of the fuel cell,
Fuel cell system. The fuel cell system according to claim 5, wherein
The calculation unit includes:
A water retention amount calculation unit that calculates the water retention amount based on a resistance value of the fuel cell at the time of startup of the fuel cell;
A generated water amount calculation unit that calculates a generated water amount based on a generated current of the fuel cell for each predetermined calculation period, and calculates the generated water amount by adding the generated power generated water amount to the water retention amount;
Fuel cell system. The fuel cell system according to claim 1, wherein
The load includes an auxiliary machine that warms up the fuel cell with the cooling water,
The limiting unit calculates a lower limit value of power supplied to the auxiliary machine as the limit value based on the temperature difference.
Fuel cell system. The fuel cell system according to claim 7, wherein
The auxiliary machine is a cooling water pump that circulates the cooling water to the parts,
The limiting unit increases the lower limit value of the power supplied to the cooling water pump higher than the target power based on the required power as the temperature difference increases.
Fuel cell system. The fuel cell system according to claim 7 or 8,
The auxiliary machine is a heater for heating the cooling water,
The limiting unit increases the lower limit value of the power supplied to the heater higher than the target power based on the required power, as the temperature difference increases.
Fuel cell system. The fuel cell system according to claim 8 , wherein
The auxiliary machine is a heater for heating the cooling water,
The limiting unit increases the power supplied to the heater to the upper limit value of the setting range after the power supplied to the cooling water pump is higher than the target power.
Fuel cell system. The fuel cell system according to any one of claims 7 to 10, wherein
When the limiting unit determines that the temperature of the component has risen to the freezing point temperature, the limiting unit releases the limitation on the generated power supplied to the load, and sets the power supplied to the auxiliary machine to a target power based on the required power. To
Fuel cell system.

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