JP5428307B2 - Fuel cell system - Google Patents

Description

  The present invention relates to a fuel cell system.

  Conventionally, a fuel gas (for example, hydrogen) is supplied to the fuel electrode, and an oxidant gas (for example, air) is supplied to the oxidant electrode, and these gases are reacted electrochemically to generate power. There is known a fuel cell system including a fuel cell for performing the above. In this type of fuel cell system, the generated water is purified in accordance with the power generation reaction, and therefore, a process for discharging it is performed.

For example, Patent Document 1 discloses a technique for discharging generated water on the fuel electrode side of a fuel cell. Specifically, when generated water accumulates on the fuel electrode side due to the power generation operation of the fuel cell, the upstream hydrogen supply valve on the fuel electrode side of the fuel cell and the drain valve on the downstream side of the fuel electrode are closed. In this state, the fuel cell generates power, and after the inside of the fuel cell and the container communicating with the fuel cell are in a decompressed state, the supply valve is opened to inject hydrogen into the decompressed fuel cell. Thereby, the generated water on the fuel electrode side of the fuel cell is pushed out into the container and discharged.
JP 2007-149630 A

  However, according to the technique disclosed in Patent Document 1, pressure fluctuation occurs inside the fuel cell when the produced water is discharged. In a high load situation, the fuel gas consumption speed is fast, and the frequency of pressure fluctuations tends to increase. For this reason, stress may occur in the components of the fuel cell and fuel gas supply system, which may lead to system degradation.

  This invention is made | formed in view of this situation, The objective is to suppress the stress which arises in the components of the system which supplies a fuel cell or fuel gas, and to suppress degradation of a system.

In order to solve this problem, the present invention controls the supply and stop of the fuel gas based on a predetermined control pattern, thereby supplying the fuel gas while periodically changing the pressure at the fuel electrode of the fuel cell. . Here, the control pattern includes a first process of reducing the pressure of the fuel electrode from the upper limit pressure to the lower limit pressure, and a second process of returning the pressure of the fuel electrode from the lower limit pressure to the upper limit pressure. At this time, when the required load is high compared to when the required load is low, the amount of fuel gas supplied in one execution period of the control pattern is increased. Further, according to the control pattern of the present invention, the first holding time for holding the pressure of the fuel electrode at the upper limit pressure before the execution of the first process, or the pressure of the fuel electrode before the execution of the second process is performed. It can be set a second hold time for holding at the lower limit pressure, the control means, the request as load is high, to set longer the first retention time or the second holding time.

  According to the present invention, since the supply amount of the fuel gas in one execution period of the control pattern is increased, an increase in the number of executions of pressure increase / decrease per unit time can be suppressed. As a result, the stress applied to the fuel cell and fuel gas supply system components can be alleviated, and system degradation can be suppressed.

(First embodiment)
FIG. 1 is a block diagram schematically showing the configuration of the fuel cell system according to the first embodiment of the present invention. The fuel cell system is mounted on, for example, a vehicle that is a moving body, and the vehicle is driven by electric power supplied from the fuel cell system.

  The fuel cell system is mainly configured by a fuel cell stack 1 configured by stacking a plurality of fuel cells. The individual fuel cells constituting the fuel cell stack 1 are configured by sandwiching a fuel cell structure in which a fuel electrode and an oxidant electrode are opposed to each other with a solid polymer electrolyte membrane interposed between a pair of separators. The fuel cell stack 1 generates electric power by electrochemically reacting the fuel gas and the oxidant gas supplied to the fuel electrode and the oxidant electrode, for each individual fuel cell.

  In the fuel cell stack 1, a pair of internal flow paths (manifolds) extending in the stacking direction of the fuel cells are configured corresponding to each of the fuel gas and the oxidant gas. Among the pair of manifolds corresponding to the fuel gas side, the supply manifold, which is one of the manifolds, supplies fuel gas to the reaction surface of the fuel electrode via the gas flow path (cell flow path) provided for each fuel cell. Gases supplied from the respective cell flow paths (hereinafter referred to as “fuel electrode off-gas”) flow into the discharge manifolds that are supplied and the other manifold, respectively. Similarly, the supply manifold, which is one of the pair of internal flow paths (manifolds) corresponding to the oxidant gas, is oxidized via the gas flow paths (cell flow paths) included in the individual fuel cells. Oxidant gas is respectively supplied to the reaction surface of the agent electrode, and gas discharged from the gas flow path (hereinafter referred to as “oxidant electrode off-gas”) flows into the discharge manifold which is the other manifold.

  Here, in this embodiment, a case where hydrogen is used as the fuel gas and air is used as the oxidant gas will be described. Also, in this specification, the terms “fuel cell”, “fuel electrode” or “oxidant electrode” are used only when referring to a single fuel cell, or its fuel electrode or oxidant electrode. Rather, it is also used when referring to all of the fuel cells constituting the fuel cell stack 1 or all of its fuel electrodes or oxidizer electrodes.

  The fuel cell system further includes a hydrogen system for supplying hydrogen to the fuel cell stack 1 and an air system for supplying air to the fuel cell stack 1.

  In the hydrogen system, hydrogen, which is a fuel gas, is stored in a fuel tank 10 (for example, a high-pressure hydrogen cylinder), and from this fuel tank 10 through a hydrogen supply channel (fuel electrode inlet channel) L1, a fuel cell stack. 1 is supplied. Specifically, one end of the hydrogen supply flow path L1 is connected to the fuel tank 10, and the other end is connected to the inlet side of the fuel gas supply manifold of the fuel cell stack 1. In the hydrogen supply flow path L1, a tank original valve (not shown) is provided downstream of the fuel tank 10, and when the tank original valve is opened, the high-pressure hydrogen gas from the fuel tank 10 The pressure is reduced to a predetermined pressure mechanically by a pressure reducing valve (not shown) provided downstream. The depressurized hydrogen gas is further depressurized by a hydrogen pressure regulating valve 11 provided downstream of the depressurizing valve, and then supplied to the fuel cell stack 1. The hydrogen pressure supplied to the fuel cell stack 1, that is, the hydrogen pressure at the fuel electrode of the fuel cell stack 1 can be adjusted by controlling the opening of the hydrogen pressure regulating valve 11. The fuel tank 10, the hydrogen supply flow path L1, and the hydrogen pressure regulating valve 11 provided in the hydrogen supply flow path L1 constitute hydrogen supply means for supplying hydrogen to the fuel electrode of the fuel cell stack 1.

  In the present embodiment, the fuel cell stack 1 is basically closed at the outlet side leading to the outside of the fuel gas discharge manifold, and the so-called closed system in which discharge of the fuel electrode off-gas from the fuel cell stack 1 is restricted. It is a system that adopts. However, this does not indicate a strict blockage, and in order to discharge impurities such as inert gas such as nitrogen and liquid water from the fuel electrode, the outlet side of the discharge manifold for fuel gas is exceptional. A discharge system is provided that opens to the front. Specifically, a fuel electrode off-gas flow path (discharge flow path) L2 is connected to the outlet side of the fuel gas discharge manifold. The other end of the fuel electrode off-gas channel L2 is connected to an oxidant electrode off-gas channel L6 described later.

  The fuel electrode off-gas flow path L2 has a predetermined capacity, for example, a volume part (volume means) having a volume equal to or about 80% of the volume on the fuel electrode side for all the fuel cells constituting the fuel cell stack 1 as a space. 12 is provided. The volume portion 12 functions as a buffer that temporarily stores the fuel electrode off-gas flowing from the fuel electrode side. A drainage flow path L3 having one end opened is connected to the lower portion of the volume portion 12 in the vertical direction, and a drainage valve 13 is provided in the drainage flow path L3. The liquid water contained in the fuel electrode off-gas flowing into the volume part 12 collects in the lower part of the volume part 12 and can be discharged by controlling the open / close state of the drain valve 13. Further, a purge valve (opening / closing means) 14 is provided in the fuel electrode off-gas flow path L2 on the downstream side of the volume portion 12. The fuel electrode off-gas flowing into the volume 12, specifically, a gas containing impurities (mainly inert gas such as nitrogen) and unreacted hydrogen is discharged by controlling the open / close state of the purge valve 14. be able to.

  On the other hand, in the air system, for example, air that is an oxidant gas is pressurized when the atmosphere is taken in by the compressor 20 and is supplied to the fuel cell stack 1 via the air supply flow path L5. The air supply flow path L5 has one end connected to the compressor 20 and the other end connected to the inlet side of the oxidant gas supply manifold in the fuel cell stack 1. The air supply flow path L5 is provided with a humidifier 21 for humidifying the air supplied to the fuel cell stack 1.

  An oxidant electrode off-gas flow path L6 is connected to the outlet side of the oxidant gas discharge manifold in the fuel cell stack 1. The oxidant electrode off-gas from the oxidant electrode in the fuel cell stack 1 is discharged to the outside through the oxidant electrode off-gas channel L6. The humidifier 21 described above is provided in the oxidant electrode off-gas flow path L6, and moisture generated by power generation is dehumidified (the dehumidified moisture is used for humidifying the supply air). An air pressure regulating valve 22 is provided downstream of the oxidant electrode off-gas flow path L6 by the humidifier 21. The air pressure supplied to the fuel cell stack 1, that is, the air pressure at the oxidant electrode of the fuel cell stack 1 can be adjusted by controlling the opening of the air pressure regulating valve 22.

  Further, the fuel cell system includes an output extraction device 30 that controls an output (for example, current) extracted from the fuel cell stack 1. The electric power generated in the fuel cell stack 1 is supplied via an output extraction device 30 to, for example, an electric motor (not shown) for driving the vehicle and various auxiliary machines necessary for the power generation operation of the fuel cell stack 1. The Moreover, the electric power generated in the output extraction device 30 is also supplied to a secondary battery (not shown). This secondary battery is provided to compensate for the shortage of power supplied from the fuel cell stack 1 at the time of system startup or transient response.

  The control unit (control means) 40 has a function of controlling the entire system in an integrated manner, and controls the operating state of the system by operating according to the control program. As the control unit 40, a microcomputer mainly composed of a CPU, a ROM, a RAM, and an I / O interface can be used. The control unit 40 performs various calculations according to a control program stored in the ROM, and outputs the calculation results to various actuators (not shown) as control signals. Thereby, the control unit 40 controls various elements such as the hydrogen pressure regulating valve 11, the drain valve 13, the purge valve 14, the compressor 20, the air pressure regulating valve 22, and the output extraction device 30, and the power generation operation of the fuel cell stack 1 is controlled. Do.

  Sensor signals from various sensors and the like are input to the control unit 40 in order to detect the state of the system. In the present embodiment, a hydrogen pressure sensor 41, an air pressure sensor 42, and a stack temperature sensor 43 are exemplified. The hydrogen pressure sensor 41 detects the pressure of hydrogen supplied to the fuel cell stack 1. The air pressure sensor 42 detects the pressure of the air supplied to the fuel cell stack 1. The stack temperature sensor 43 detects the temperature of the fuel cell stack 1.

  The controller 40 controls the fuel cell system in the form shown below. The control unit 40 supplies air and hydrogen to the fuel cell stack 1, thereby generating power by the fuel cell stack 1. In this case, the control unit 40 supplies air and hydrogen so that the pressure of air and hydrogen supplied to the fuel cell stack 1 becomes a predetermined operating pressure. This operating pressure is set, for example, as a constant reference value regardless of the power generated by the fuel cell stack 1 or as a variable value corresponding to the power generated by the fuel cell stack 1.

  In the present embodiment, the control unit 40 performs pressure control according to a predetermined operating pressure for the air supply to the oxidant electrode. On the other hand, the control unit 40 controls the supply and stop of hydrogen according to a control pattern for increasing and decreasing the pressure within the range between the upper limit pressure P1 and the lower limit pressure P2 for the hydrogen supply of the fuel electrode. Then, by repeating the operation according to the control pattern, the control unit 40 supplies hydrogen to the fuel electrode while periodically changing the hydrogen pressure at the fuel electrode of the fuel cell stack 1 as shown in FIG. To do.

  Specifically, the control unit 40 performs the hydrogen adjustment on the assumption that the hydrogen pressure of the fuel electrode has reached the upper limit pressure P1 and that a sufficient hydrogen concentration for generating power is secured in the fuel electrode. The pressure valve 11 is controlled to the minimum opening, and the supply of hydrogen to the fuel cell stack 1 is stopped. When the control unit 40 continues to extract the load current corresponding to the required load required for the system from the fuel cell stack 1 via the output extraction device 30, hydrogen is consumed by the power generation reaction. The pressure drops. Next, the control unit 40 controls the hydrogen pressure regulating valve 11 to the maximum opening degree on the condition that the hydrogen pressure of the fuel electrode has decreased to the lower limit pressure P2, and restarts the supply of hydrogen to the fuel cell stack 1. Thereby, the hydrogen pressure in the fuel electrode increases. And the control part 40 stops supply of hydrogen again by controlling the hydrogen pressure regulation valve 11 to the minimum opening degree on the condition that the hydrogen pressure reached | attained (returned) the upper limit pressure P1. By repeating such a series of processes as a one-cycle control pattern, the control unit 40 supplies hydrogen to the fuel electrode of the fuel cell stack 1 while periodically changing the hydrogen pressure.

  Here, for the upper limit pressure P1 and the lower limit pressure P2, for example, an upper limit side pressure and a lower limit side pressure are set based on a prescribed operating pressure. The hydrogen pressure at the fuel electrode of the fuel cell stack 1 can be monitored by referring to the detection value of the hydrogen pressure sensor 41. Further, when the pressure is increased, it is desirable that the hydrogen pressure on the upstream side of the hydrogen pressure regulating valve 11 is sufficiently high to increase the pressure increasing rate as much as possible. For example, the pressure increase period from the lower limit pressure P2 to the upper limit pressure P1 is set to about 0.1 to 0.5 seconds. On the other hand, the time from the upper limit pressure P1 to the lower limit pressure P2 is about 1 to 10 seconds, but depends on the upper limit pressure P1, the lower limit pressure P2, and the current value taken out from the fuel cell stack 1, that is, the hydrogen consumption rate.

  In hydrogen supply control with such periodic pressure increase / decrease, as one of the features of the present embodiment, the control pattern includes holding times Tp1, Tp2 for holding the pressure of the fuel electrode at the upper limit pressure P1 or the lower limit pressure P2. Can be set. The controller 40 can arbitrarily set the first and second holding times Tp1 and Tp2 in the range from zero to a predetermined value.

  As shown in FIG. 3, the first holding time Tp1 holds the pressure of the fuel electrode at the upper limit pressure P1 before the first step of reducing the pressure of the fuel electrode from the upper limit pressure P1 to the lower limit pressure P2. It is time to do. Specifically, the control unit 40 controls the opening degree Ot of the hydrogen pressure regulating valve 11 to the maximum opening degree O1 on the condition that the pressure of the fuel electrode has decreased to the lower limit pressure P2, whereby the fuel cell stack 1 The hydrogen supply is resumed to increase the fuel electrode pressure. The control unit 40 reduces the opening Ot of the hydrogen pressure regulating valve 11 from the maximum opening O1 to a predetermined opening, on the condition that the pressure of the fuel electrode has reached the upper limit pressure P1, and increases the pressure of the fuel electrode to the upper limit. Hold at pressure P1. Then, the control unit 40 sets the opening degree Ot of the hydrogen pressure regulating valve 11 to the minimum opening degree O2 on the condition that the first holding time Tp1 has elapsed from the timing when the pressure of the fuel electrode reaches the upper limit pressure P1. By controlling, the supply of hydrogen to the fuel cell stack 1 is stopped.

  On the other hand, as shown in FIG. 4, the second holding time Tp2 is such that the pressure of the fuel electrode is increased before the execution of the second process of increasing the pressure of the fuel electrode from the lower limit pressure P2 to the upper limit pressure P1. This is the time for holding at the lower limit pressure P2. Specifically, the control unit 40 controls the opening degree Ot of the hydrogen pressure regulating valve 11 to the minimum opening degree O2 on the condition that the pressure of the fuel electrode has reached the upper limit pressure P1, and supplies the fuel cell stack 1 to the fuel cell stack 1. The supply of hydrogen is stopped. The control unit 40 increases the opening degree Ot of the hydrogen pressure regulating valve 11 from the minimum opening degree O2 to a predetermined opening degree on the condition that the hydrogen pressure of the fuel electrode has decreased to the lower limit pressure P2, and thereby increases the pressure of the fuel electrode. The lower limit pressure P2 is maintained. Then, the control unit 40 sets the opening degree Ot of the hydrogen pressure regulating valve 11 to the maximum opening degree O1 on the condition that the second holding time Tp2 has elapsed from the timing when the pressure of the fuel electrode reaches the lower limit pressure P2. By controlling, the supply of hydrogen to the fuel cell stack 1 is resumed, and the pressure of the fuel electrode is increased.

  FIG. 5 is an explanatory diagram showing the correspondence between the load and each holding time Tp1, Tp2. For example, when the system operation scene is a low load (for example, a state in which a load current is taken out to about 1/3 or less of the rated load current), the first and second holding times Tp1, Tp2 are set to zero. ing. In the case of a medium load (for example, a load current extraction state in a range larger than about 1/3 and smaller than about 2/3 with respect to the rated load current), the first holding time Tp1 is set to zero. The second holding time Tp2 is set so that the value increases as the load increases, starting from zero. In addition, in the case of a high load (for example, a state in which a load current of about 2/3 or more with respect to the rated load current is taken out), the first holding time Tp1 increases as the load increases starting from zero. The second holding time Tp2 is set to a constant value. Thus, the control unit 40 can determine the first and second holding times Tp1, Tp2 according to the load state. In other words, whether to hold the fuel electrode pressure at the upper limit pressure P1 or the lower limit pressure P2 can be selected according to the load.

  As described above, in this embodiment, the control unit 40 increases the supply amount of hydrogen in one execution period of the control pattern when the required load is high (when the load current is large) compared to when the load is low. Yes. In an operating scene such as a high load, the hydrogen consumption tends to be large. Therefore, in order to cover the supply of hydrogen, there is a possibility that the number of executions of pressure increase / decrease corresponding to one control pattern increases. However, according to this embodiment, since the supply amount of hydrogen in one execution period of the control pattern is increased, an increase in the number of executions of pressure increase / decrease per unit time can be suppressed. As a result, stress applied to the fuel cell stack 1 and the hydrogen-based components can be alleviated, so that deterioration of the system can be suppressed.

  In the present embodiment, the control pattern is the first holding time Tp1 in which the pressure of the fuel electrode is held at the upper limit pressure P1 before the execution of the first process, or the pressure of the fuel electrode before the execution of the second process. Can be set at a second holding time Tp2. Then, the control unit 40 sets the first holding time Tp1 or the second holding time Tp2 longer as the required load is higher. As the required load increases, the amount of hydrogen consumption increases, so the pressure drop rate in the second process increases. However, according to the present embodiment, the greater the required load, the greater the first holding time Tp1 or second The holding time Tp2 is set to be long. Thereby, it is possible to set a long period from the timing when the pressure of the fuel electrode reaches the upper limit pressure P1 to the timing when the pressure of the fuel electrode is returned from the lower limit pressure P2 to the upper limit pressure P1. That is, since the one execution period of the control pattern is lengthened by the holding times Tp1 and Tp2, an increase in the number of executions of pressure increase / decrease per unit time can be suppressed. As a result, stress applied to the fuel cell stack 1 and the hydrogen-based components can be alleviated, so that deterioration of the system can be suppressed.

  In particular, the control unit 40 preferably sets the first holding time Tp1 longer as the required load is higher. When the required load increases, it may become difficult to ensure the hydrogen partial pressure at the fuel electrode. Therefore, by setting the first holding time Tp1 at the upper limit pressure P1 to be long, there is an effect that the hydrogen partial pressure is easily ensured even when the required load is high.

  In the present embodiment, the second holding time Tp2 is set longer as the required load increases in the region where the required load is low to medium. From low to medium loads, liquid water tends to accumulate in the fuel electrode. By setting the second holding time Tp2 at the lower limit pressure P2 to be long, the execution accuracy of the liquid water discharge process can be increased. Furthermore, it is preferable that the control unit 40 sets the first holding time Tp1 longer as the required load becomes higher in a region where the required load is medium load to high load. When the required load increases, it may become difficult to ensure the hydrogen partial pressure at the fuel electrode. Therefore, by setting the first holding time Tp1 at the upper limit pressure P1 to be long, there is an effect that the hydrogen partial pressure is easily ensured even when the required load is high.

  In addition, as shown in FIG. 6, the hydrogen holding pressure is ensured by setting the first holding time P1 for holding the upper limit pressure P1 longer in the scene where the concentration of impurities such as nitrogen in the fuel electrode is higher immediately after startup. May be. At this time, the longer the time from the stop to the start, the higher the inert gas concentration in the fuel electrode. Therefore, the time for holding the upper limit pressure may be varied by measuring the stop period or measuring the nitrogen concentration in the fuel electrode at the time of startup.

  Furthermore, in a system that employs an idle stop that temporarily stops power generation of the fuel cell stack 1 and travels with the power of the secondary battery, such as during low loads, the nitrogen concentration in the fuel electrode immediately after returning from the idle stop Is in a high situation. Therefore, the first holding time P1 may be set longer in such a scene.

(Second Embodiment)
The fuel cell system according to the second embodiment of the present invention will be described below. In the present embodiment, a method for setting the upper limit pressure P1 and the lower limit pressure P2 will be described.

  As a first method, the upper limit pressure P1 and the lower limit pressure P2 can be set according to the load current. The control unit 40 determines the target generated power of the fuel cell stack 1 as a required load required for the system based on the vehicle speed, the accelerator operation amount of the driver, and information on the secondary battery. The control unit 40 calculates a load current, which is a current value extracted from the fuel cell stack 1, based on the target generated power.

  FIG. 7 is an explanatory diagram showing a correspondence relationship between the load current Ct and the upper limit pressure P1 and the lower limit pressure P2. The operating pressure Psa for supplying the reaction gas necessary for taking out the load current Ct from the fuel cell stack 1 is determined based on the characteristics of the system such as the fuel cell stack 1, the hydrogen system and the air system. Can be defined through. When supplying air to the oxidizer electrode, this operating pressure Psa is set as the target operating pressure.

On the other hand, when hydrogen is supplied to the fuel electrode, an upper limit pressure P1 and a lower limit pressure P2 are set based on the operating pressure Psa. Here, the upper limit pressure P1 and the lower limit pressure P2 are set so as to increase the differential pressure between the upper limit pressure P1 and the lower limit pressure P2, that is, the pressure fluctuation range during gas supply, as the load current Ct increases. Yes.

  According to such a configuration, the amount of hydrogen supplied in one execution period of the control pattern can be relatively increased in a scene with a higher required load. Thereby, the increase in the frequency | count of execution of the pressure increase / decrease per unit time can be suppressed. Thereby, degradation of the system can be suppressed.

  As a second method, the upper limit pressure P1 and the lower limit pressure P2 may be set in consideration of the power generation stability of the fuel cell stack 1. In the case of a low load, that is, when the load current is small, for example, the pressure is set to about 50 kPa so that the differential pressure between the upper limit pressure P1 and the lower limit pressure P2 becomes relatively small. In this case, the average hydrogen concentration in each fuel cell is about 40%. On the other hand, when the load is high, that is, when the load current is large, increasing the gas pressure increases the power generation efficiency. Therefore, the supply pressure is increased as a whole on both the oxidant electrode side and the fuel electrode side. The differential pressure between the upper limit pressure P1 and the lower limit pressure P2 is set to about 100 kPa. In this case, the operation is performed at an average hydrogen concentration in each fuel cell of about 75%.

  In this embodiment in which the pressure is periodically increased and decreased, the atmosphere inside the fuel cell stack 1 (fuel electrode) is in a state where the hydrogen concentration is low at the timing of the lower limit pressure P2, and the hydrogen concentration is at the timing of the upper limit pressure P1. Become high. That is, by increasing the pressure from the lower limit pressure P2 to the upper limit pressure P1, a high hydrogen concentration gas is introduced into the fuel electrode, whereby a low hydrogen concentration gas is pushed from the fuel cell stack 1 into the volume portion 12. Further, the gas in the fuel electrode is agitated by the gas having a high hydrogen concentration.

  FIG. 8 is an explanatory view schematically showing the volume Rs on the fuel electrode side and the volume Rt of the volume portion 12 in the fuel cell stack 1. For example, when the upper limit pressure P1 is 200 kPa (absolute pressure) and the lower limit pressure P2 is 150 kPa (absolute pressure), the pressure ratio P1 / P2 between the upper limit pressure P1 and the lower limit pressure P2 is approximately 1.33. In this case, as shown in FIG. 9A, 1 of the volume of the fuel system (specifically, the volume of the fuel cell stack 1 and the volume portion 12) is increased by the pressure increase from the lower limit pressure P2 to the upper limit pressure P1. / 4, that is, new hydrogen flows up to 50% of the fuel cell stack 1 (hereinafter, this state is expressed as a hydrogen exchange rate of 0.5 (see FIG. 5B)).

  When the load is low, the consumption rate of hydrogen is slow, so that the fuel cell stack 1 can generate power at a hydrogen exchange rate of about this level. In this scene, for example, the time-averaged hydrogen concentration in the anode off-gas is about 40%. On the other hand, in the case of a high load, the pressure ratio P1 / P2 (for example, 2 or more), that is, the hydrogen exchange rate is about 1 so that the entire fuel electrode of the fuel cell stack 1 is replaced with new hydrogen. Is desirable. Although the hydrogen concentration to be discharged is desired to be kept low, the hydrogen consumption rate is fast, so that a certain hydrogen concentration or more is necessary for stable power generation (for example, about 75% or more is required).

  In such a case, the fuel electrode off-gas flow path L2 is opened by the purge valve 14 in order to adjust the hydrogen concentration. As a result, a minute flow rate that does not hinder the supply of hydrogen due to periodic pressure fluctuations is continuously or intermittently discharged from the purge valve 14. Since the gas discharged from the purge valve 14 has a minute flow rate, it is diluted by the exhaust on the cathode side and safely discharged out of the system. The purge valve 14 is opened to discharge impurities (nitrogen and water vapor) from the fuel electrode, but hydrogen is also mixed in the fuel electrode. Therefore, it is preferable to effectively discharge impurities while suppressing hydrogen discharge.

  Therefore, in the present embodiment, in the hydrogen supply, the purge valve 14 is controlled to be opened and opened in response to a process (second process) of increasing the pressure from the lower limit pressure P2 to the upper limit pressure P1. (Purge process). Specifically, the control unit 40 monitors the pressure of the fuel electrode of the fuel cell stack 1 and controls the purge valve 14 to open in response to the timing when it reaches the lower limit pressure P2, which is also the upper limit pressure P1. The purge valve 14 is controlled to be in a closed state corresponding to the timing when it has reached (basic control pattern). As a result, the low hydrogen concentration gas is pushed from the fuel cell stack 1 into the volume portion 12 and before the high concentration hydrogen reaches the purge valve 14, the low hydrogen concentration gas passes through the purge valve 14. Discharged. Thereby, it becomes possible to discharge many impurities efficiently.

  However, the opening / closing control of the purge valve 14 is not limited to this basic control pattern, and it is sufficient that the purge valve 14 is controlled to be opened so as to include at least a process of increasing the pressure from the lower limit pressure P2 to the upper limit pressure P1. . Therefore, the timing at which the purge valve 14 is controlled to be closed can be corrected to a timing delayed from the timing at which the hydrogen pressure reaches the upper limit pressure P1 (hereinafter referred to as “reference closing timing”). For example, the boundary between high-concentration hydrogen and low-concentration hydrogen can be determined as a constant surface within a short time range when considering the diffusion rate. Therefore, at the time of supply of hydrogen, the position at which the boundary surface (so-called hydrogen front) arrives in the fuel cell stack 1 and the volume portion 12 is predicted through experiments and simulations. The timing for controlling the purge valve 14 to the closed state can be delayed from the reference closing timing until the boundary surface reaches the purge valve 14.

  Further, the purge process does not have to be performed for every execution of the control pattern, specifically, for each of the pressure increase processes (second processes). For example, the purge valve 14 may be opened in response to the subsequent pressure increasing process on condition that the hydrogen concentration in the fuel electrode is equal to or higher than a determination threshold value.

  Moreover, since liquid water is also considered as a factor that inhibits the power generation reaction, it may be discharged together. However, since the time until the liquid water is affected is longer than the presence of the inert gas, the liquid water is discharged not once every time the pressure is periodically increased / decreased, but once every multiple times or every fixed time. It is preferable to execute the process. Since the liquid water only needs to be removed from the fuel cell stack 1, it is considered that the liquid water is discharged from the fuel cell stack 1 to the volume portion 12. In this case, since it is necessary to increase the flow velocity, it is preferable to set the differential pressure between the upper limit pressure P1 and the lower limit pressure P2 to about 100 kPa.

  The upper limit pressure P1 and the lower limit pressure P2 may be set in consideration of the following additional method in addition to the method of varying the required load as described above. First, as a first additional method, the upper limit pressure P1 and the lower limit pressure P2 may be set according to the allowable inter-electrode differential pressure between the oxidant electrode and the fuel electrode in the fuel cell.

  In addition, as a second additional method, in a system that performs a purge process for discharging the inert gas accumulated in the fuel electrode, an upper limit is set so as to ensure a minimum pressure for reliably performing the purge. The pressure P1 and the lower limit pressure P2 may be limited.

  Further, as a third additional method, it is predicted that the higher the nitrogen concentration in the fuel electrode, the larger the upper limit pressure P1 is set, and the larger the liquid water retention amount or liquid water generation amount in the fuel electrode is. In this state, the lower limit pressure P2 is set to a small value. Thereby, when it is determined that the liquid water has actually accumulated, a large pressure difference is secured, so that the liquid water can be reliably discharged.

  Further, as a fourth additional method, in a scene where the amount of liquid water in the fuel cell stack 1 is estimated to be large, as shown in FIG. 9, the upper limit pressure P1 and the lower limit pressure P2 are The upper limit pressure P1 and the lower limit pressure P2 are set so that the pressure ratio (P1 / P2) temporarily becomes a large value (P1w / P2w). The pressure width (P1-P2) necessary for discharging the liquid water in the fuel electrode is, for example, 100 kPa or more, and the pressure width for discharging the inert gas in the fuel electrode is, for example, 50 kPa or more. is there. Since the pressure widths of the two are thus different, the upper limit pressure P1 and the lower limit pressure P2 are set as described above from the viewpoint of liquid water discharge.

  Here, when the upper limit pressure P1 is set high as in the above-described method, since the hydrogen consumption rate is low in the low load region, the rate at which the pressure decreases from the upper limit pressure P1 to the lower limit pressure P2 becomes slow. In this case, since it takes time to reach the lower limit pressure P2, there is a possibility that the first process of increasing the pressure to the upper limit pressure P1 cannot be executed for a while.

  Therefore, as shown in FIG. 10, when the upper limit pressure P1 is set to a high value (for example, pressure P1w) at the time of low load, the control unit 40 temporarily increases the current taken out from the fuel cell stack 1 to The descending speed may be increased. For example, when the current is not increased, the time required to decrease from the upper limit pressure P1w to the lower limit pressure P2 is the time Tm2, whereas by increasing the current, the upper limit pressure P1w is changed to the lower limit pressure P2. The time required for the decrease is such that the time Tm3 is shorter than the time Tm2. Thereby, the interference with the control of the pressure increase / decrease for the inert gas discharge and the control of the pressure increase / decrease for the next liquid water discharge can be suppressed.

  In addition, when the voltage of the fuel cell stack 1 is lowered, the power generation state may be unstable by temporarily increasing the current extracted from the fuel cell stack 1, or the extracted current is stored. When the charge level of the secondary battery is high, the pressure drop rate may be increased by another method instead of increasing the extraction current.

  Another method for increasing the pressure drop speed is, for example, to increase the flow rate of the fuel electrode off-gas discharged from the purge valve 14. Further, the pressure decreasing speed may be increased by increasing the volume of the fuel electrode. As a method for expanding the volume of the fuel electrode, it is possible to lower the management level of the liquid water in the fuel electrode and discharge the liquid water in the fuel electrode.

  As a method for estimating the amount of liquid water staying in the fuel electrode, it is conceivable to estimate the amount of liquid water based on the characteristic that the amount of liquid water produced is approximately proportional to the load current. Moreover, you may estimate by the elapsed time from the liquid water discharge timing performed previously. Alternatively, the voltage of the fuel cell may be measured, and it may be estimated that the amount of liquid water staying is large due to the abnormal drop in voltage. Further, when the liquid water retention amount is estimated, it may be corrected by the temperature of the cooling water that cools the fuel cell stack 1. This is because even if the load current is the same, the lower the cooling water temperature, the more liquid water stays. Similarly, it is also possible to correct by the number of pressure pulsations and the amount of cathode air.

(Third embodiment)
Hereinafter, a fuel cell system according to a third embodiment of the present invention will be described. In the first embodiment, the processing at the time of normal operation in which power generation corresponding to the load current is performed in the fuel cell stack 1 has been described. In the present embodiment, processing at the time of system startup and at the time of system shutdown will be described. . In addition, since the structure of a fuel cell system is the same as 1st Embodiment, suppose that the overlapping description is abbreviate | omitted and demonstrates centering on difference below.

  First, the activation process will be described. When the fuel cell stack 1 is left for a while without being started immediately after the system is stopped, the fuel electrode is filled with a gas having a low hydrogen concentration. When the fuel cell system is started in such a situation, the low hydrogen concentration gas is discharged from the fuel electrode of the fuel cell stack 1, so that the high hydrogen concentration gas is discharged from the fuel tank 10 to a predetermined starting upper limit pressure. Is supplied instantaneously to increase the gas pressure at the fuel electrode. At this time, the purge valve 14 is also controlled to open. As a result, the passage of the hydrogen front, which is the boundary surface between the low hydrogen concentration gas and the high hydrogen concentration gas, can be accelerated, and the hydrogen front can be pushed out of the fuel electrode.

  Next, before the timing at which the hydrogen front reaches the purge valve 14, the hydrogen pressure regulating valve 11 and the purge valve 14 are controlled to be closed, power is generated, and hydrogen is consumed, so that the hydrogen pressure at the fuel electrode is reduced. Let When the hydrogen pressure reaches a predetermined starting lower limit pressure, the pressure is increased again to a predetermined starting upper limit pressure. Then, such pressure increase / decrease is repeated until the concentration of the fuel electrode of the fuel cell stack 1 reaches a predetermined average hydrogen concentration.

  In an actual vehicle, there is a possibility that the vehicle starts while such a startup process is being executed. In this case, the output from the mounted secondary battery may be used.

  Next, the stop process will be described. Assuming a low temperature environment as a start scene after the stop, if liquid water is present in the fuel cell stack 1 and the valve at the stop, the start may be impossible due to freezing or the like. Therefore, the process for removing this liquid water at the time of a stop is needed. First, power is generated in a low load state while supplying air to the oxidizer electrode. On the fuel electrode side, the pressure increase / decrease is repeated according to the control pattern as in the first embodiment. In this case, for example, the upper limit pressure P1 is set to 200 kPa (absolute pressure) and the lower limit pressure P2 is set to 101.3 kPa, and values sufficient to discharge liquid water from the fuel electrode are set. The number of repetitions is based on the number of times that liquid water can be sufficiently discharged through experiments and simulations. This terminates power generation.

  Next, the liquid water discharged from the fuel cell stack 1 to the volume portion 12 is drained by controlling the drain valve 13 in the open state. Then, using the electric power generated immediately before draining, heating means such as a heater is operated, and the purge valve 14 and the drain valve 13 are heated and dried. As described above, according to the present embodiment, the startability at the time of start-up can be achieved by the stop processing, and impurities can be preferentially discharged over hydrogen even at the time of start-up processing.

1 is a block diagram schematically showing the configuration of a fuel cell system according to a first embodiment. Explanatory diagram showing changes in pressure increase and decrease at the fuel electrode Explanatory drawing of 1st holding time Tp1 Explanatory drawing of 2nd holding time Tp2 Explanatory drawing of holding time Tp1, Tp2 and load Explanatory drawing of holding time Tp1, Tp2 and load Explanatory drawing of load current and upper limit pressure P1 and lower limit pressure P2 Explanatory drawing which shows typically the volume Rs of the fuel electrode side and the volume Rt of the volume part 12 in the fuel cell stack 1. Explanatory drawing of upper limit pressure P1 and lower limit pressure P2 Illustration of pressure drop speed

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Fuel cell stack 2 ... Fuel gas supply manifold 3 ... Fuel gas discharge manifold 10 ... Fuel tank 11 ... Hydrogen pressure regulating valve 12 ... Volume control part 13 ... Drain valve 14 ... Purge valve 15 ... Gas-liquid separator 20 ... Compressor 21 DESCRIPTION OF SYMBOLS ... Humidifier 22 ... Air pressure regulating valve 30 ... Output extraction device 40 ... Control part L1 ... Hydrogen supply flow path L2 ... Fuel electrode off gas flow path L3 ... Drain flow path L5 ... Air supply flow path L6 ... Oxidant electrode off gas flow path

Claims (4)

A fuel cell that generates electric power by electrochemically reacting an oxidant gas supplied to the oxidant electrode and a fuel gas supplied to the fuel electrode;
Fuel gas supply means for supplying the fuel gas to the fuel electrode of the fuel cell;
Output extraction means for extracting output from the fuel cell;
By controlling the output extraction means, the output corresponding to the required load required for the system is extracted from the fuel cell, and the supply and stop of the fuel gas by the fuel gas supply means are controlled based on a predetermined control pattern Control means for supplying the fuel gas while periodically changing the pressure at the fuel electrode of the fuel cell,
The control pattern includes a first step of reducing the pressure of the fuel electrode from an upper limit pressure to a lower limit pressure, and a second step of returning the pressure of the fuel electrode from the lower limit pressure to the upper limit pressure. ,
The control means increases the supply amount of the fuel gas in one execution period of the control pattern when the required load is high and when the required load is low ,
The control pattern further includes a first holding time for holding the pressure of the fuel electrode at an upper limit pressure before the execution of the first process, or a lower limit of the pressure of the fuel electrode before the execution of the second process. A second holding time to hold at pressure can be set;
Wherein, the request as load is high, the fuel cell system characterized that you set longer the first retention time or the second holding time. A fuel cell that generates electric power by electrochemically reacting an oxidant gas supplied to the oxidant electrode and a fuel gas supplied to the fuel electrode;
Fuel gas supply means for supplying the fuel gas to the fuel electrode of the fuel cell;
Output extraction means for extracting output from the fuel cell;
By controlling the output extraction means, the output corresponding to the required load required for the system is extracted from the fuel cell, and the supply and stop of the fuel gas by the fuel gas supply means are controlled based on a predetermined control pattern Control means for supplying the fuel gas while periodically changing the pressure at the fuel electrode of the fuel cell,
The control pattern includes a first step of reducing the pressure of the fuel electrode from an upper limit pressure to a lower limit pressure, and a second step of returning the pressure of the fuel electrode from the lower limit pressure to the upper limit pressure. ,
The control means increases the supply amount of the fuel gas in one execution period of the control pattern when the required load is high and when the required load is low,
The control pattern can set a first holding time for holding the pressure of the fuel electrode at an upper limit pressure before the execution of the first process,
2. The fuel cell system according to claim 1, wherein the control unit sets the first holding time to be longer as the required load is higher. 2. The fuel cell system according to claim 1 , wherein the control unit sets the second holding time longer as the required load becomes higher in a region where the required load is low load to medium load. . 2. The fuel cell system according to claim 1 , wherein the control means sets the first holding time longer as the required load becomes higher in a region where the required load is medium load to high load. .

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