JP5277596B2 - Fuel cell system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To improve responsiveness of generated electric power without leading to increase in size and cost of parts of gas supply system. <P>SOLUTION: A controller 40 has an integrated control mode and an individual control mode, as a switchable control mode. After determining the single target generation electric power, based on this target generation electric power, the integrated control mode here integrally controls an operating state of a fuel gas supplying means and an oxidizer gas supplying means and the operating state of an electric power taking out means. On the other hand, after determining mutually different target generation electric powers, based on the individual target generation electric power, the individual control mode individually controls the operating state of the fuel gas supplying means and the oxidizer gas supplying means, and the operating state of the electric power taking out means. <P>COPYRIGHT: (C)2009,JPO&amp;INPIT

Description

  The present invention relates to a fuel cell system mounted on a moving body driven by electric power.

  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. This fuel cell system is mounted on, for example, a mobile body (specifically, a vehicle), and is driven by receiving power supply from the system by supplying power generated by the fuel cell to a drive motor. To do. In such a system, a power storage means is also incorporated in order to compensate for the shortage of power from the fuel cell.

In a fuel cell system, operation is normally performed in a normal power generation mode in which power is supplied to a moving body from power generated by the fuel cell. However, from the viewpoint of improving fuel efficiency, when the predetermined judgment condition is satisfied, the power generation by the fuel cell is stopped, and the operation is performed in the power generation stop mode in which the power supply to the moving body is performed from the power stored in the power storage means. Is done.
JP 2003-303605 A

  By the way, when the fuel cell is operated, a target generated power that is a target value of the generated power of the fuel cell is determined, and based on the determined target generated power, a gas supply means such as a fuel gas or an oxidant gas is used. The operating state and the operating state of the power extraction means are respectively determined. In this case, when the fuel cell is started from a state where power generation is suspended, such as when the power generation suspension mode is shifted to the normal power generation mode, the response to the gas supply means is made in comparison with the response of the power extraction means. There may be a delay in sex. For this reason, a situation occurs in which the extraction current is set excessively in a state where the gas supply amount is insufficient, and the response of the generated power may be delayed.

  The present invention has been made in view of such circumstances, and an object thereof is to improve the responsiveness of generated power.

  In order to solve this problem, in the fuel cell system of the present invention, the control means has an integrated control mode and an individual control mode as switchable control modes. Here, in the integrated control mode, after determining a single target generated power, based on the target generated power, the operating state of the fuel gas supply means and the oxidant gas supply means, the operating state of the power extraction means, Is controlled in an integrated manner. On the other hand, in the individual control mode, different target generated powers are determined, and based on the individual target generated powers, the operating state of the fuel gas supply means and the oxidant gas supply means and the operating state of the power extraction means are determined. Control individually.

  According to the present invention, when the individual control mode is used as the control mode, the operating state of the fuel gas supply unit and the oxidant gas supply unit and the operating state of the power extraction unit can be individually controlled. Therefore, since the gas supply including the fuel gas and the oxidant gas and the current extraction can be controlled individually, the situation where the gas supply is insufficient for the current extraction can be suppressed, and the response of the generated power It is possible to improve the performance.

(First embodiment)
FIG. 1 is a block diagram showing the overall 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.

  A fuel cell system is a fuel cell stack (fuel cell) in which a fuel cell structure in which a solid polymer electrolyte membrane is sandwiched between an oxidant electrode and a fuel electrode is sandwiched between separators, and a plurality of them are stacked. ) 1 is provided. The fuel cell stack 1 is configured such that fuel gas is supplied to individual fuel electrodes and oxidant gas is supplied to individual oxidant electrodes, whereby these gases are reacted electrochemically to generate generated power. Occur. In the present embodiment, a case where hydrogen is used as the fuel gas and oxygen is used as the oxidant gas will be described.

  The fuel cell system includes a hydrogen system for supplying hydrogen to the fuel cell stack 1, an air system for supplying air to the fuel cell stack 1, and a cooling system for cooling the fuel cell stack 1. It has been.

  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 is supplied from the fuel tank 10 to the fuel cell stack 1 via the hydrogen supply flow path L1. Specifically, a fuel tank original valve 11 is provided downstream of the fuel tank 10, and when the fuel tank original valve 11 is opened, the high-pressure hydrogen gas from the fuel tank 10 is provided downstream thereof. The pressure reducing valve 12 is mechanically reduced to a predetermined pressure. The decompressed hydrogen gas is further decompressed by a hydrogen pressure regulating valve 13 provided downstream of the decompression valve 12 and then supplied to the fuel cell stack 1.

  Exhaust gas from the fuel electrode (gas containing unused hydrogen) is discharged from the fuel cell stack 1 to the hydrogen circulation passage L2. The other end of the hydrogen circulation flow path L2 is connected to the hydrogen supply flow path L1 on the downstream side of the hydrogen pressure regulating valve 13, and the hydrogen circulation flow path L2 includes, for example, a hydrogen such as a hydrogen circulation pump 14. Circulation means are provided. By driving the hydrogen circulation pump 14, the exhaust gas from the fuel electrode is circulated through the hydrogen circulation channel L2 to the hydrogen supply channel L1 (that is, the hydrogen supply side in the fuel electrode).

  Here, the hydrogen pressure regulating valve 13 and the hydrogen circulation pump 14 function as fuel gas supply means for supplying fuel gas to the fuel electrode of the fuel cell stack 1, and the operating state thereof is controlled by a controller 40 described later. The In the present embodiment, as an example, a method of changing the supply amount of hydrogen by controlling the operating state of the hydrogen pressure regulating valve 13, that is, the opening degree thereof will be described.

  By the way, in the case of using air as the oxidant gas, since impurities in the air permeate from the oxidant electrode to the fuel electrode, the impurities in the hydrogen circulation passage L2 including the fuel electrode increase and the hydrogen partial pressure decreases. Tend to. Here, the impurity is a non-fuel gas component other than hydrogen which is a fuel gas, and can be typically exemplified by nitrogen (hereinafter, in this embodiment, description will be made using nitrogen as an impurity for convenience). If the amount of nitrogen increases too much, the output from the fuel cell stack 1 may decrease, or hydrogen may not be circulated by the hydrogen circulation pump 14. Therefore, it is necessary to manage the amount of nitrogen in the hydrogen circulation passage L2 including the fuel electrode. Therefore, the hydrogen circulation flow path L2 is provided with a discharge flow path L3 for discharging the gas flowing therethrough to the outside. A purge valve 15 is provided in the discharge flow path L3, and the amount of nitrogen discharged to the outside through the discharge flow path L3 can be adjusted by adjusting the opening amount of the purge valve 15. Further, the discharge flow path L3 is provided with a hydrogen dilution device 16, and the hydrogen discharged simultaneously with the discharge of nitrogen is mixed with air by the hydrogen dilution device 16 before being discharged outside the vehicle. Diluted. The opening amount of the purge valve 15 is appropriately controlled by the controller 40. Thereby, the nitrogen amount existing in the fuel electrode and the hydrogen circulation passage L2 is managed so that the power generation performance and the circulation performance can be maintained.

  In the air system, for example, the air that is an oxidant gas is pressurized while the atmosphere is taken in by the compressor 20, and the pressurized air is supplied to the fuel cell stack 1 via the air supply flow path L4. The air supply channel L4 is provided with a humidifier (not shown), and the air supplied to the fuel cell stack 1 is humidified to such an extent that the power generation performance of the fuel cell stack 1 is not deteriorated. Exhaust gas (air in which oxygen has been consumed) from the fuel cell stack 1 is discharged to the outside through the air discharge channel L5. An air pressure regulating valve 21 is provided in the air discharge channel L5.

  Here, the compressor 20 and the air pressure regulating valve 21 function as an oxidant gas supply means for supplying an oxidant gas to the oxidant electrode of the fuel cell stack 1, and its operating state is controlled by the controller 40. . In the present embodiment, as an example, a method of changing the supply amount of air by controlling the operating state of the compressor 20, that is, the number of rotations thereof will be described.

  The cooling system has a closed loop cooling flow path L6 through which cooling water for cooling the fuel cell stack 1 circulates, and a cooling water circulation pump 31 for circulating the cooling water is provided in the cooling flow path L6. Yes. By operating this cooling water circulation pump 31, the cooling water in the cooling flow path L6 circulates. Further, the cooling flow path L6 is provided with a radiator 32 and a fan 33 that blows air to the radiator 32. The cooling water whose temperature has risen due to the cooling of the fuel cell stack 1 flows to the radiator 32 via the cooling flow path L6 and is cooled by the radiator 32. The cooled cooling water is supplied to the fuel cell stack 1. The flow path of the cooling flow path L6 is finely branched in the fuel cell stack 1, so that the inside of the fuel cell stack 1 is cooled throughout. The driving amounts of the cooling water circulation pump 31 and the fan 33 are controlled by the controller 40 based on the cooling water temperature discharged from the fuel cell stack 1.

  A power manager (power extraction means) 2 is connected to the fuel cell stack 1. The power manager 2 is controlled by the controller 40, extracts electric power from the fuel cell stack 1, and supplies the extracted electric power to the electric motor 3 that drives the vehicle.

  A secondary battery (power storage means) 4 is connected to the power manager 2 and the electric motor 3, and the secondary battery 4 has the following functions. First, electric power necessary to drive various auxiliary machines (for example, the hydrogen circulation pump 14 and the compressor 20) operated to generate electric power in the fuel cell stack 1 is supplied. Secondly, when the power generated in the fuel cell stack 1 is insufficient with respect to the power required for the system (required power), the insufficient power is supplied to the electric motor 3. Third, when the generated power of the fuel cell stack 1 becomes surplus with respect to the required power, the surplus power is stored and the regenerative power of the electric motor 3 is stored.

  The controller 40 has a function of controlling the entire system, and controls the operating state of the fuel cell stack 1 by controlling each part of the system according to the control program. As the controller 40, a microcomputer mainly composed of a CPU, a ROM, a RAM, and an I / O interface can be used. The controller 40 performs various calculations based on the state of the system, and outputs the calculation results to various actuators (not shown) as control outputs. The hydrogen pressure adjusting valve 13, the hydrogen circulation pump 14, and the purge valve 15 are output. The compressor 20, the air pressure regulating valve 21, the cooling water circulation pump 31, the fan 33, and the power manager 2 are controlled. The controller 40 receives signals from various sensors as control inputs in order to detect the system state.

  The hydrogen pressure sensor 17 is a sensor that detects the hydrogen pressure supplied to the fuel electrode of the fuel cell stack 1. The air pressure sensor 22 is a sensor that detects the air pressure supplied to the oxidant electrode of the fuel cell stack 1. The air flow rate sensor 23 is a sensor that detects the flow rate of air supplied to the oxidant electrode of the fuel cell stack 1. The cooling water temperature sensor 34 is a sensor that detects the temperature of the cooling water discharged from the fuel cell stack 1. The voltage sensor 6 detects the voltage in the fuel cell stack 1, specifically, for each single cell that is the minimum power generation element, or for each set of a plurality of adjacent single cells. The vehicle speed sensor 7 is a sensor that detects the vehicle speed of the vehicle from the wheel speed of the vehicle or the rotation speed of the electric motor 3. The accelerator opening sensor 8 is a sensor that detects an operation amount of the accelerator pedal (accelerator operation amount) by the driver and detects this as an acceleration request amount of the driver.

  In addition, the electric power consumed by itself is transmitted from the electric motor 3 to the controller 40, and the battery including the remaining amount of power stored in the secondary battery 4 and the power that can be output from the secondary battery 4 is transmitted from the battery controller 5. Information is being sent. Further, the compressor 20 transmits electric power consumed by itself to the controller 40, and the power manager 2 transmits an extraction current, which is an electric current extracted from the fuel cell stack 1, in order to perform electric power extraction control.

  FIG. 2 is a block diagram functionally showing the configuration of the controller 40. When the controller 40 grasps this functionally, the integrated control unit 41, the gas supply system control unit 42, the extraction current system control unit 43, the operation determination unit 44, and the mode switching unit (mode switching unit) function as a control unit. 45). In order to execute the function, the controller 40 refers to the vehicle speed Vc detected by the vehicle speed sensor 7, the accelerator operation amount Ac detected by the accelerator opening sensor 8, and the battery information Bi transmitted from the battery controller 5. In addition, the controller 40 also includes calculation result information (hereinafter referred to as “integrated calculation information”) Vic and various detection values (hereinafter referred to as “stack detection information”) Dfc related to the fuel cell stack 1 in the control units 41 to 43. refer. Here, the stack detection information Dfc is the hydrogen pressure by the hydrogen pressure sensor 17, the air pressure by the air pressure sensor 22, the air flow rate by the air flow sensor 23, the cooling water temperature by the cooling water temperature sensor 34, the voltage by the voltage sensor 6, and the like. is there.

  The integrated control unit 41 determines a single target generated power Pst and, based on the target generated power Pst, integrates gas supply to the fuel cell stack 1 and current extraction from the fuel cell stack 1. Control. The integrated control unit 41 includes a generated power determination unit 41a, an extraction current determination unit 41b, a valve opening determination unit 41c, and a rotation speed determination unit 41d.

  Based on the vehicle speed Vc, the accelerator operation amount Ac, and the battery information Bi, the generated power determining unit 41a determines a target generated power Pst that is a target value of power generated in the fuel cell stack 1. The extraction current determination unit 41b determines a target extraction current At that is a target value of the current to be extracted from the fuel cell stack 1 based on the target generated power Pst. The valve opening degree determination unit 41c determines a target supply amount (flow rate) and a target pressure of hydrogen to the fuel cell stack 1 based on the target generated power Pst, and based on this, determines the opening degree of the hydrogen pressure regulating valve 13. A target opening degree Oht, which is a target value, is determined. The rotation speed determination unit 41d determines a target supply amount (flow rate) and a target pressure of air to the fuel cell stack 1 based on the target generated power Pst, and based on this, is a target value of the rotation speed of the compressor 20. A target rotational speed Rat is determined.

  The gas supply system control unit 42 individually controls only gas supply to the fuel cell stack 1. The gas supply system control unit 42 includes a generated power determination unit 42a, a valve opening determination unit 42b, and a rotation speed determination unit 42c.

  The generated power determination unit 42a determines the first target generated power P1t based on the vehicle speed Vc, the accelerator operation amount Ac, and the battery information Bi. The valve opening degree determination unit 42b determines a target supply amount (flow rate) and target pressure of hydrogen to the fuel cell stack 1 based on the first target generated power P1t, and based on this, the hydrogen pressure regulating valve 13 The target opening degree Oht is determined. The rotation speed determination unit 41d determines a target supply amount (flow rate) and a target pressure of air to the fuel cell stack 1 based on the first target generated power P1t, and based on this, the target rotation speed Rat of the compressor 20 is determined. To decide.

  The extraction current system control unit 43 has a function of individually controlling only current extraction from the fuel cell stack 1. The extraction current system control unit 43 includes a generated power determination unit 43a and an extraction current determination unit 43b.

  The generated power determination unit 42a determines the second target generated power P2t based on the vehicle speed Vc, the accelerator operation amount Ac, and the battery information Bi. The extraction current determination unit 41b determines a target extraction current At from the fuel cell stack 1 based on the second target generated power P2t.

  The operation determination unit 44 is in a situation where control is performed using the integrated control unit 41 based on the accelerator operation amount Ac, the vehicle speed Vc, the battery information Bi, the integrated calculation information Vic, and the stack detection information Dfc. In the situation where the integrated control mode is used, or in the situation where the control is performed using the gas supply system control unit 42 and the extraction current system control unit 43 respectively, that is, in the situation where the individual control mode is used. Determine if there is (control mode decision). In addition, when the individual control mode is used, the operation determination unit 44 determines the timing for using the gas supply system control unit 42 and the extraction current system control unit 43, respectively. The operation determining unit 44 uses the integrated control mode when the operation mode to be described later is the normal power generation mode, and uses the individual control mode in a scene where the operation mode is switched from the power generation suspension mode to the normal power generation mode. Transition from the control mode to the integrated control mode.

  The mode switching unit 45 switches the operation mode of the fuel cell stack 1 between the normal power generation mode and the power generation suspension mode based on the accelerator operation amount Ac, the vehicle speed Vc, and the battery information Bi. The normal power generation mode is a mode in which power is supplied to the vehicle (specifically, the electric motor 3) from the power generated by the fuel cell stack 1, while the power generation suspension mode is a mode in which the fuel cell stack 1 generates power. In this mode, power is supplied to the vehicle from the power stored in the secondary battery 4 after stopping. The mode switching unit 45 normally selects the normal power generation mode as the operation mode, supplies the reaction gas (air and hydrogen), and performs power generation according to the required power in the fuel cell stack 1. The mode switching unit 45 switches the operation mode from the normal power generation mode to the power generation suspension mode when the power generation suspension is permitted. When the operation mode is set to the power generation stop mode, the mode switching unit 45 stops the supply of the reaction gas (air and hydrogen) and stops the power generation by the fuel cell stack 1.

  FIG. 3 is a flowchart showing a procedure of operation mode setting processing according to the embodiment of the present invention. The processing shown in this flowchart is called at a predetermined cycle, and is executed mainly by the controller 40, specifically, the mode switching unit 45.

  First, in step 10 (S10), it is determined whether or not the accelerator operation amount Ac is equal to or less than the determination accelerator operation amount Acth. The determination accelerator operation amount Acth is a value for determining whether the driver is depressing or not depressing the accelerator pedal, and an optimal value is set in advance through experiments and simulations (for example, Acth = 0). When an affirmative determination is made in step 10, that is, when the accelerator operation amount Ac is equal to or less than the determination accelerator operation amount Acth (Ac ≦ Acth), the process proceeds to step 11 (S11). On the other hand, if a negative determination is made in step 10, that is, if the accelerator operation amount Ac is greater than the determined accelerator operation amount Acth (Ac> Acth), the process proceeds to step 13 (S13).

  In step 11, it is determined whether or not the vehicle speed Vc is equal to or lower than the determination vehicle speed Vcth. The determination vehicle speed Vcth is a value for determining whether or not the vehicle speed has decreased to such an extent that the power generation of the fuel cell stack 1 can be stopped, and an optimal value is set in advance through experiments and simulations. (For example, Vcth = 20 km / h). If the determination in step 11 is affirmative, that is, if the vehicle speed Vc is equal to or less than the vehicle speed determination value Vcth (Vc ≦ Vcth), the process proceeds to step 12 (S12). On the other hand, if a negative determination is made in step 11, that is, if the vehicle speed Vc is greater than the vehicle speed determination value Vcth (Vc> Vcth), the process proceeds to step 13.

  In step 12, it is determined whether or not the remaining amount of the secondary battery 4 (remaining battery amount) exists sufficiently based on the battery information Bi. Specifically, it is determined whether or not the remaining amount of electricity necessary for continuously stopping the power generation of the fuel cell stack 1 for one minute or more and whether or not the output power is equal to or greater than a predetermined power threshold value. If the determination in step 12 is affirmative, that is, if the remaining battery level is sufficient, the process proceeds to step 15 (S15) described later. On the other hand, if a negative determination is made in step 12, that is, if the remaining battery level is not sufficient, the process proceeds to step 13.

  In step 13, the mode switching unit 45 sets the operation mode to the normal power generation mode on condition that any one of the accelerator operation amount Ac, the vehicle speed Vc, and the remaining battery level does not satisfy the determination condition.

  In step 14 (S14), the operation determination unit 44 sets the control mode as a condition that any one of the accelerator operation amount Ac, the vehicle speed Vc, and the remaining battery level does not satisfy the determination condition in the mode switching unit 45. Start (continue) the integrated control mode. That is, after the process of step 14, gas supply to the fuel cell stack 1 and current extraction from the fuel cell stack 1 are controlled by the integrated control unit 41.

  On the other hand, in step 15, the mode switching unit 45 stops the power generation by the fuel cell stack 1 on condition that all the parameters of the accelerator operation amount Ac, the vehicle speed Vc, and the battery remaining amount satisfy the determination conditions. (Power generation stop permission).

  In step 16 (S16), the operation determining unit 44 individually sets the control mode on the condition that all the parameters of the accelerator operation amount Ac, the vehicle speed Vc, and the battery remaining amount satisfy the determination conditions in the mode switching unit 45. Enter control mode. That is, after the process of step 14, the gas supply to the fuel cell stack 1 is controlled by the gas supply system control unit 42, and the current extraction from the fuel cell stack 1 is controlled by the extraction current system control unit 43.

  In step 17 (S17), the mode switching unit 45 sets the operation mode to the power generation suspension mode.

  Hereinafter, the integrated control mode will be described. FIG. 4 is an explanatory diagram showing a processing concept of the integrated control mode. The generated power determination unit 41a calculates the target torque of the electric motor 3 based on the output power of the secondary battery 4 that is the battery information Bi, the accelerator operation amount Ac, and the vehicle speed Vc. Based on the actual rotational speed of the electric motor 3, the target generated power Pst in the fuel cell stack 1 is determined.

  Specifically, it is assumed that the driver depresses the accelerator pedal while a vehicle of a certain weight and shape is traveling at a predetermined vehicle speed, and the vehicle speed change rate (acceleration) and driving desired in that case are assumed. By designing the acceleration feeling felt by the user in advance, the target torque of the electric motor 3 can be calculated based on the accelerator operation amount Ac and the vehicle speed Vc. Based on the target torque of the electric motor 3 and the actual rotational speed of the electric motor 3, the expected power consumption of the electric motor 3, that is, the target generated power can be calculated.

  Here, when the target torque of the electric motor 3 is determined without considering the responsiveness of the fuel cell stack 1, the output power from the secondary battery 4 may increase due to the response delay of the fuel cell stack 1. There is sex. In this case, overdischarge occurs and the secondary battery 4 may be deteriorated. Therefore, as shown in FIG. 4C, on the premise of the electric power Pw (solid line) necessary for realizing the accelerating force, the responsiveness of the fuel cell stack 1 and the output possible power of the secondary battery 4 (hatching region) In consideration of the above, the target torque of the electric motor 3 is determined, and thereby the target generated power Pst of the fuel cell is determined.

  FIG. 5 is an explanatory diagram showing calculation processing of the extraction current determination unit 41b, the valve opening determination unit 41c, and the rotation speed determination unit 41d in the integrated control unit 41. Based on the target generated power Pst, the valve opening degree determination unit 41c determines the hydrogen supply amount to the fuel cell stack 1 and the hydrogen pressure in the fuel cell stack 1 necessary for generating the target generated power Pst. Based on the hydrogen supply amount and the hydrogen pressure, the target opening degree Oht of the hydrogen pressure regulating valve 13 necessary for realizing this is determined. The rotation speed determining unit 41d determines the air supply amount to the fuel cell stack 1 and the air pressure in the fuel cell stack 1 necessary for generating the target generated power Pst based on the target generated power Pst. Then, based on the air supply amount and the air pressure, the target rotational speed Rat of the compressor 20 necessary for realizing this is determined. The extraction current determination unit 41b determines the target extraction current At of the power manager 2 based on the target generated power Pst. When these control parameters, that is, the target opening degree Oht of the hydrogen pressure regulating valve 13, the target rotational speed Rat of the compressor 20, and the target extraction current At of the power manager 2, are determined, the hydrogen pressure regulating valve 13, the compressor 20 and the power are determined. The manager 2 is controlled according to the control parameters, and supply of hydrogen and air to the fuel cell stack 1 and current extraction from the fuel cell stack 1 are performed.

  Hereinafter, the individual control mode will be described. FIG. 6 is a flowchart illustrating a processing procedure of the individual control mode according to the first embodiment. FIG. 7 is an explanatory diagram of the first and second target generated powers P1t and P2t. The process shown in the flowchart of FIG. 6 is executed mainly by the controller 40, specifically, the operation determination unit 44 with the start of the power generation suspension mode as the operation mode.

  First, in step 20 (S20), the motion determination unit 44 determines whether or not the accelerator pedal operation amount has increased based on the accelerator operation amount Ac. If an affirmative determination is made in step 20, that is, if the accelerator pedal operation amount has increased, the process proceeds to step 21 (S21). On the other hand, if a negative determination is made in step 20, that is, if the accelerator pedal operation amount has not increased, the same determination is made after a predetermined time.

  In step 21, the operation determination unit 44 causes the gas supply system control unit 42 to start arithmetic processing related to gas supply to the fuel cell stack 1. Accordingly, the generated power determination unit 42a of the gas supply system control unit 42 determines the electric motor 3 based on the output power of the secondary battery 4 that is the battery information Bi, the accelerator operation amount Ac, and the vehicle speed Vc. The target torque is calculated, and the first target generated power P1t is determined based on the target torque and the actual rotational speed of the electric motor 3.

  In the individual control mode, the power generation suspension mode is started as the operation mode. Therefore, even if the power generation by the fuel cell stack 1 is started according to the accelerator operation, the response is delayed. Therefore, when the amount of power stored in the secondary battery 4 is large and the output power is high, by performing the power generation suspension mode, even in the power generation suspension mode, while maintaining the same responsiveness as during acceleration, By stopping the operation, the fuel efficiency can be improved.

  However, if the target output power of the fuel cell stack 1 is calculated in consideration of the high output possible power of the secondary battery 4 and the responsiveness of the fuel cell stack 1 on the premise of the power generation halt mode, the compressor 20. Operation start of the hydrogen pressure regulating valve 13 is delayed. Therefore, the responsiveness of the generated power is not different from that in the integrated control unit 41. Therefore, the generated power determination unit 42a determines the target generated power without considering the increase in the output power of the secondary battery 4 on the assumption of the power generation halt mode, and determines this as the first target generated power P1t. To do. In other words, the generated power determination unit 42a of the gas supply system control unit 42 is responsive so as to be faster than the generated power determination unit 41a of the integrated control unit 41, that is, in the individual control mode than in the integrated control mode. The first target generated power P1t is determined so as to have a quick response.

  In the gas supply system control unit 42, the valve opening degree determination unit 42 b is similar to the valve opening degree determination unit 41 c of the integrated control unit 41, based on the first target generated power based on P1t. A hydrogen supply amount to the fuel cell stack 1 necessary for generating P1t and a hydrogen pressure in the fuel cell stack 1 are determined. Based on the hydrogen supply amount and the hydrogen pressure, the target opening degree Oht of the hydrogen pressure regulating valve 13 necessary for realizing this is determined. Similarly to the rotation speed determination unit 41d of the integrated control unit 41, the rotation speed determination unit 42c is necessary for generating the first target generated power P1t based on the first target generated power P1t. The amount of air supplied to the fuel cell stack 1 and the air pressure in the fuel cell stack 1 are determined. Then, based on the air supply amount and the air pressure, the target rotational speed Rat of the compressor 20 necessary for realizing this is determined. When these control parameters, that is, the target opening degree Oht of the hydrogen pressure regulating valve 13 and the target rotational speed Rat of the compressor 20 are determined, the hydrogen pressure regulating valve 13 and the compressor 20 are controlled according to the control parameters, and the fuel cell stack 1 Hydrogen and air are supplied to the vehicle.

  In step 22 (S22), the motion determination unit 44 determines whether or not the accelerator pedal operation amount has decreased based on the accelerator operation amount Ac. If an affirmative determination is made in step 22, that is, if the amount of operation of the accelerator pedal has decreased, the process proceeds to step 23 (S23). On the other hand, if a negative determination is made in step 22, that is, if the accelerator pedal operation amount has not decreased, the process proceeds to step 24 (S24).

  In step 23 (S23), the operation determination unit 44 causes the gas supply system control unit 42 to stop the arithmetic processing related to the gas supply to the fuel cell stack 1. Accordingly, the gas supply system control unit 42 (specifically, the valve opening degree determination unit 42b and the rotation speed determination unit 42c) adjusts the hydrogen pressure so as to stop the supply of hydrogen and air to the fuel cell stack 1. After setting the target opening degree Oht of the valve 13 and the target rotational speed Rat of the compressor 20, the process proceeds to step 20.

  In step 24 (S24), the operation determination unit 44 determines whether or not the first target generated power P1t in the gas supply system control unit 42 is equal to or less than the determination power P1th. The determination power P1th is a power determination value for determining switching from the power generation suspension mode to the normal power generation mode, and an optimal value is set in advance through experiments and simulations. If an affirmative determination is made in step 24, that is, if the first target generated power P1t is equal to or less than the determination power P1th, the process proceeds to step 25 (S25). On the other hand, when a negative determination is made in step 24, that is, when the first target generated power P1t is larger than the determination power P1th, the process proceeds to step 27 (S27) described later.

  In step 25, the operation determination unit 44 determines whether or not the vehicle speed Vc is equal to or lower than the determination vehicle speed Vcth. This determination is the same as the processing shown by step 11 in FIG. If the determination in step 25 is affirmative, that is, if the vehicle speed Vc is equal to or less than the vehicle speed determination value Vcth (Vc ≦ Vcth), the process proceeds to step 26 (S26). On the other hand, if a negative determination is made in step 25, that is, if the vehicle speed Vc is greater than the vehicle speed determination value Vcth (Vc> Vcth), the process proceeds to step 27.

  In step 26, the operation determination unit 44 determines whether or not the remaining amount of the secondary battery 4 (remaining battery amount) exists sufficiently based on the battery information Bi. This determination is the same as the processing shown by step 12 in FIG. If an affirmative determination is made in step 26, that is, if the remaining battery level is sufficient, the process proceeds to step 22 described above. On the other hand, if a negative determination is made in step 26, that is, if the remaining battery level is not sufficient, the process proceeds to step 27.

  In step 27, the operation determining unit 44 is in a state where the power is insufficient when any of the parameters of the first target generated power P1t, the vehicle speed Vc, and the remaining battery level does not satisfy the determination condition. That is, the mode switching unit 45 determines that the operation mode has been switched from the power generation suspension mode to the normal power generation mode, and causes the extraction current system control unit 43 to start arithmetic processing related to the extraction current from the fuel cell stack 1. Accordingly, in the extraction current system control unit 43, the generated power determination unit 43a is capable of outputting the secondary battery 4 that is battery information Bi from the same viewpoint as the generated power determination unit 41a of the integrated control unit 41, and The target torque of the electric motor 3 is calculated based on the accelerator operation amount Ac and the vehicle speed Vc, and the second target generated power P2t is determined based on the target torque and the actual rotational speed of the electric motor 3. . However, the second target generated power P2t is set to have a power generation response earlier than the target generated power Pst determined by the generated power determining unit 41a of the integrated control unit 41.

  In step 28 (S28), the operation determination unit 44 determines whether or not the control mode can be switched from the individual control mode to the integrated control mode. Specifically, the operation determination unit 44 refers to the integrated calculation information Vic and the stack detection information Dfc, and calculates the target extraction current At, the hydrogen target pressure, the air target flow rate, and the target pressure calculated in the integrated control unit 41. Determines whether or not the actual detected value is approached. If an affirmative determination is made in step 28, the operation proceeds to step 29 (S29). On the other hand, if a negative determination is made in step 28, the same determination is made after a predetermined time.

  In step 29 (S29), the operation determining unit 44 shifts from the individual control mode to the integrated control mode as the control mode. Specifically, the operation determination unit 44 collectively switches the control subject from the gas supply system control unit 42 and the extraction current system control unit 43 to the integrated control unit 41. However, the operation determination unit 44 may individually switch the gas supply system control unit 42 and the extraction current system control unit 43 to the integrated control unit 41.

  As described above, according to the present embodiment, the controller 40 includes the integrated control unit 41, the gas supply system control unit 42, the extraction current system control unit 43, and the operation determination unit 44, so that the integrated control mode and the individual control mode are provided. Can be executed as a switchable control mode. When the individual control mode is used as the control mode, the gas supply means including the fuel gas supply means (hydrogen pressure regulating valve 13 in the present embodiment) and the oxidant gas supply means (compressor 20 in the present embodiment). The operating state and the operating state of the power extraction means (in this embodiment, the power manager 2) can be individually controlled. Therefore, the gas supply including hydrogen and air and the current extraction can be controlled individually, so that the situation where the gas supply is insufficient for the current extraction can be suppressed, and the responsiveness of the generated power is improved. Can be achieved. Further, since only gas supply and current extraction are individually controlled, it is possible to improve the responsiveness of the generated power of the fuel cell stack 1 without increasing the size of the parts and increasing the cost. Furthermore, since the integrated control mode is used in addition to the individual control mode, the target generated power for calculating the gas supply and current extraction is obtained by using the integrated control mode except for using the individual control mode. Can be shared. Thereby, the increase in calculation load can be suppressed.

  Further, according to the present embodiment, the controller 40 includes the mode switching unit 45. When the operation mode is the normal power generation mode, the controller 40 uses the integrated control mode, uses the individual control mode in a scene where the operation mode switches from the power generation halt mode to the normal power generation mode, and then integrates from the individual control mode. Transition to control mode. In the power generation halt mode, since the power generation of the fuel cell stack 1 is halted, when there is a power generation request, it takes time to resume power generation, and the power generation responsiveness becomes worse compared to that in the normal power generation mode. There is. In this regard, according to the present embodiment, gas supply and current extraction can be individually controlled by using the individual control mode in a scene where the operation mode is switched from the power generation suspension mode to the normal power generation mode. Therefore, it is possible to suppress a situation where the gas supply is insufficient with respect to the current extraction, and it is possible to improve the response of the generated power.

  In the present embodiment, in the individual control mode, when the operation state of the gas supply unit is controlled in advance and it is determined that the operation mode is switched from the power generation suspension mode to the normal power generation mode, the operation state of the power extraction unit Control is started. Thereby, gas supply can be performed before the operation mode is switched to the normal power generation mode. Thereby, since gas supply can be performed prior to current extraction, it is possible to suppress a situation in which gas supply is insufficient with respect to current extraction and responsiveness deteriorates.

  In the present embodiment, the controller 40 determines the operating state of the fuel gas supply means for the target generated power, the operating state of the oxidant gas supply means for the target generated power, and the operating state of the power extraction means for the target generated power, The calculation is performed corresponding to each of the integrated control mode and the individual control mode. Thereby, the calculation regarding each operation state can be made common in the integrated control mode and the individual control mode. Thereby, the increase in calculation load can be suppressed.

  In the present embodiment, the controller 40 determines the target generated power in the individual control mode so that the responsiveness is faster in the gas supply means operating state than in the operating state of the power extraction means. Thereby, since gas supply can be performed prior to current extraction, it is possible to suppress a situation in which gas supply is insufficient with respect to current extraction and the responsiveness of generated power deteriorates.

(Second Embodiment)
FIG. 8 is an explanatory diagram showing calculation processing of the valve opening degree determination unit 42b and the rotation speed determination unit 42c of the gas supply system control unit 42 according to the second embodiment. The fuel cell system according to the second embodiment is different from that of the first embodiment in the processing contents in the gas supply system control unit 42. In addition, the description which overlaps with embodiment mentioned above shall be abbreviate | omitted, and demonstrates below centering on difference.

  Specifically, in the gas supply system control unit 42, the valve opening determination unit 42b determines the target opening of the hydrogen pressure regulating valve 13 as follows. The valve opening degree determination unit 42b determines a necessary hydrogen supply amount and a hydrogen pressure based on the first target generated power P1t determined by the generated power determination unit 42a, and based on this, determines the hydrogen regulating valve 13's. The target opening degree Oht is calculated. Here, in the case where the first target generated power P1t is small, the hydrogen target pressure is calculated as a small value, and the target opening degree Oht corresponding to this is calculated. At this time, the supplied hydrogen amount is calculated from the calculated target opening degree Oht, and the pressure increase value in the hydrogen system due to the supply of this hydrogen amount is calculated. When this calculation result is smaller than the pressure resistance value of the pressure applied to the electrolyte membrane or the pressure resistance value of the pressure difference between the hydrogen system internal pressure and the atmospheric pressure, the target is set to increase the supply amount within the range of the pressure resistance value. The opening degree Oht is corrected, and the corrected target opening degree Ohta is calculated. By using the corrected target opening degree Ohta, the hydrogen supply amount can be further increased. Here, when the pressure resistance value is large, the target opening degree Oht can be corrected within the upper limit range of the fully opened opening degree of the hydrogen pressure regulating valve 13. Note that when the target opening degree Oht is calculated, it may be calculated using the pressure resistance value.

  Further, in the gas supply system control unit 42, the rotational speed determination unit 42c also corrects the target rotational speed Rat of the compressor 20 calculated based on the first target generated power P1t, similarly to the valve opening degree determination unit 42b. Then, the corrected target rotational speed Rata is calculated. By using the corrected target rotation speed Rata, the air supply amount can be further increased. The details of the correction method are the same as those of the valve opening degree determination unit 42b, and the description thereof is omitted. When the pressure resistance value is large, the target rotational speed Rat can be corrected within the upper limit range of the maximum rotational speed of the compressor 20.

  Based on the corrected target opening degree Ohta and the corrected target rotational speed Rat, the hydrogen pressure regulating valve 13 and the compressor 20 are controlled, and hydrogen and air are supplied to the fuel cell stack 1.

  As described above, in the present embodiment, in the individual control mode, the controller 40 sets the operating state of the fuel gas supply means (in this embodiment, the hydrogen pressure regulating valve 13) determined based on the target generated power P1t to the system. Correction is made so that the supply amount of hydrogen is increased with the allowable range of pressure resistance as the upper limit. Thereby, since hydrogen supply amount can be set much, the improvement of the responsiveness of generated electric power can be aimed at. Such actions and effects can be similarly applied to the oxidant gas supply means (the compressor 20 in this embodiment). In this case, since a large amount of air supply can be set, it is possible to improve the response of the generated power.

  In the individual control mode, the controller 40 increases the supply amount of the fuel gas with the operating state of the fuel gas supply means determined based on the target generated power P1t as the upper limit of the maximum operating state allowed by the system. You may correct | amend as follows. Thereby, since hydrogen supply amount can be set much, the improvement of the responsiveness of generated electric power can be aimed at. Such actions and effects can be similarly applied to the oxidant gas supply means (the compressor 20 in this embodiment). In this case, since a large amount of air supply can be set, it is possible to improve the response of the generated power.

(Third embodiment)
FIG. 9 is a flowchart illustrating the processing procedure of the individual control mode according to the third embodiment. The fuel cell system according to the third embodiment is different from that of the first or second embodiment in the processing contents of the individual control mode. In addition, the description which overlaps with embodiment mentioned above shall be abbreviate | omitted, and demonstrates below centering on difference.

  In step 21, when the operation determination unit 44 causes the gas supply system control unit 42 to start calculation processing related to gas supply to the fuel cell stack 1, the fuel cell is controlled according to the calculation processing of the gas supply system control unit 42. Hydrogen and air are supplied to the stack 1. However, when an affirmative determination is made in all of steps 24 to 26, that is, when the power generation halt mode is continued, the supply of hydrogen and air is continued, but the current consumption is not taken out from the fuel cell stack 1. The bad state continues. Therefore, in step 31 (S31), the operation determination unit 44 determines whether or not the supply amounts of hydrogen and air calculated by the gas supply system control unit 42 are equal to or greater than a determination value for determining deterioration in fuel consumption. . If an affirmative determination is made in step 31, the process proceeds to step 32 (S32). On the other hand, if a negative determination is made in step 32, the process of step 32 is skipped and the process proceeds to step 22.

  In step 32, the operation determining unit 44 causes the extraction current system control unit 43 to set the target extraction current At to a fixed value. The larger the target extraction current At can be set, the larger the supply amount of hydrogen and air can be set. The electric power extracted at this time needs to be stored mainly in the secondary battery 4. Therefore, as shown in FIG. 10, the target opening degree Oht of the hydrogen pressure regulating valve 13 and the target rotational speed Rat of the compressor 20 are corrected based on the remaining amount of electricity stored as battery information Bi. Based on the corrected target opening degree Ohta and the corrected target rotational speed Rat, the hydrogen pressure regulating valve 13 and the compressor 20 are controlled, and hydrogen and air are supplied to the fuel cell stack 1.

  On the other hand, in step 30 (S30) following step 23, the operation determination unit 44 causes the extraction current system control unit 43 to cancel the setting of the target extraction current At and stops the extraction of current from the fuel cell stack 1. .

  As described above, in the present embodiment, in the individual control mode, the controller 40 sets the operating state of the gas supply means so that the amount of fuel gas supplied increases as the power that can be stored in the secondary battery 4 increases. It correct | amends so that the supply amount of oxidant gas may increase. According to such a configuration, since the gas supply amount can be increased, it is possible to suppress a situation in which the gas supply is insufficient with respect to the extraction current and the responsiveness is deteriorated, and power storage in the secondary battery 4 is possible. Since the gas supply amount can be increased in accordance with the available power, the generated power can be effectively collected in the secondary battery 4, and the deterioration of fuel consumption can be suppressed.

  In addition, when the operating state of the gas supply unit becomes larger than the determination state, the generated power can be effectively collected in the secondary battery 4 by determining the operating state of the power extraction unit. Can be prevented.

(Fourth embodiment)
FIG. 11 is a flowchart illustrating the processing procedure of the individual control mode according to the fourth embodiment. The fuel cell system according to the fourth embodiment differs from that of the first to third embodiments in the processing contents of the individual control mode. In addition, the description which overlaps with embodiment mentioned above shall be abbreviate | omitted, and demonstrates below centering on difference. In the present embodiment, the processing of steps 20 and 24 described above is omitted, and the processing of step 33 (S33) is added to the processing timing of step 20 concerned.

  In step 33, the generated power determination unit 42a of the gas supply system control unit 42 determines the electric motor 3 based on the output power of the secondary battery 4 that is the battery information Bi, the accelerator operation amount Ac, and the vehicle speed Vc. The target torque is calculated, and the first target generated power P1t is determined based on the target torque and the actual rotational speed of the electric motor 3. Then, the generated power determining unit 42a determines whether or not the first target generated power P1t is equal to or greater than the determination power P1th. If an affirmative determination is made in step 33, that is, if the first target generated power P1t is greater than or equal to the determination power P1th (P1t ≧ P1th), the process proceeds to step 21 (S21). On the other hand, when a negative determination is made in step 33, that is, when the first target generated power P1t is smaller than the determination power P1th (P1t <P1th), the same determination is performed after a predetermined time.

  In step 21, the operation determination unit 44 causes the gas supply system control unit 42 to start arithmetic processing related to gas supply to the fuel cell stack 1. As a premise of this, the generated power determination unit 42a of the gas supply system control unit 42 performs a secondary operation in a period from the timing when the accelerator operation amount Ac increases to the timing when the first target generated power P1t becomes equal to or higher than the determination power P1th. The rate of change of the electric power taken out from the battery 4 is calculated in advance.

  As shown in FIG. 12, in a scene of acceleration from a low vehicle speed, such as when the vehicle is stopped, the rotation rate of the electric motor 3 is small, so the rate of change of the calculated first target generated power P1t is slow. Therefore, there is a possibility that the first target generated power P1t and the second target generated power P2t have the same magnitude and the same rate of change, the voltage of the fuel cell stack 1 decreases, and the generated voltage decreases. there's a possibility that. Therefore, since it is necessary to suppress the occurrence of such a situation, the generated power determination unit 42a calculates the rate of change of power as described above, and if this rate of change is below a predetermined value, The first target generated power P1t is corrected to a value larger than the calculated value. This increases the supply amount of hydrogen and air. The predetermined value to be compared with the rate of change is based on the fact that the voltage of the fuel cell does not decrease by changing the timing and rate of change of the generation current with respect to the supply change rate of air and hydrogen and the correction amount. Set through experiments and simulations.

  As described above, in the present embodiment, the controller 40 is determined based on the target generated power when the rate of change of the power taken out from the secondary battery 4 is equal to or less than the determination threshold in the individual control mode. The operating state of the gas supply means is corrected so that the gas supply amount increases. According to this configuration, the target generated power of the gas supply system (first target generated power P1t) and the target generated power of the current extraction system (second target generated power P2t) have the same magnitude and the same rate of change. Therefore, a situation in which the voltage of the fuel cell stack 1 decreases and the generated voltage decreases can be suppressed.

(Fifth embodiment)
FIG. 13 is a block diagram showing an overall configuration of a fuel cell system according to the fifth embodiment. The fuel cell system according to the fifth embodiment is different from that of the first to fourth embodiments in that an air supply cutoff valve (oxidant gas cutoff means) 24 is provided in the air system. In addition, the description which overlaps with embodiment mentioned above shall be abbreviate | omitted, and demonstrates below centering on difference.

  As shown in the figure, an air supply cutoff valve 24 is provided downstream of the compressor 20 in the fuel supply flow path L4. The air supplied to the fuel cell stack 1 can be shut off by switching the air supply shut-off valve 24 from the open state to the closed state. The open / closed state of the air supply cutoff valve 24 is controlled by the controller 40, specifically, the gas supply system control unit 42.

  FIG. 14 is a flowchart illustrating the processing procedure of the individual control mode according to the fifth embodiment. In the present embodiment, the processing of steps 34 and 35 relating to the control of the air supply cutoff valve 24 is added.

  Specifically, in step 34 (S 34) following the affirmative determination in step 20, the operation determination unit 44 outputs a valve closing instruction for the air supply cutoff valve 24 to the gas supply system control unit 42. In response to this instruction, the gas supply system control unit 42 switches the air supply cutoff valve 24 from the open state to the closed state. Then, the process proceeds to step 21 described above.

  In Step 35 (S35) following the negative determination of any one of Steps 24-26, the operation determining unit 44 instructs the gas supply system control unit 42 to open the air supply shut-off valve 24. Output. In response to this instruction, the gas supply system control unit 42 switches the air supply cutoff valve 24 from the closed state to the open state. Then, the process proceeds to step 27 described above.

  As described above, in the present embodiment, the controller 40 oxidizes the air supply cutoff valve 24 during the period from the start of the control of the operating state of the oxidant gas supply unit to the start of the control of the operating state of the power extraction unit. Shut off the agent gas. According to this configuration, since the voltage of the fuel cell stack 1 is suppressed to the open-circuit voltage in a situation where gas supply is performed in advance, deterioration of the fuel cell stack 1 can be suppressed. In addition, since the rotation speed of the compressor 20 can be set to a high value at the start of power generation, the responsiveness of the generated power can be further improved.

(Sixth embodiment)
FIG. 15 is a flowchart illustrating a processing procedure of the individual control mode according to the sixth embodiment. The difference of the fuel cell system according to the sixth embodiment from that of the first to fifth embodiments is the processing content of the individual control mode. In addition, the description which overlaps with embodiment mentioned above shall be abbreviate | omitted, and demonstrates below centering on difference.

  In the present embodiment, in step 36 (S36) following the affirmative determination in step 22, the operation determination unit 44 determines whether or not a predetermined time has elapsed from the timing when the operation amount of the accelerator pedal has decreased. If an affirmative determination is made in step 36, the process proceeds to step 23. On the other hand, if a negative determination is made in step 36, the process returns to step 20. The determination in Step 36 has a function of setting a waiting time until the process proceeds to Step 23, and the optimum value is set in advance for the predetermined time through experiments and simulations.

Thus, according to this embodiment, the controller 40 is
After starting the control of the operating state of the gas supply means, the determined operating state is reduced even if the acceleration request amount to the moving body decreases until the start of the control of the operating state of the power extraction means Keep without letting. According to such a configuration, even if the acceleration request amount is temporarily reduced, the gas supply is continuously maintained, so that deterioration of fuel consumption can be suppressed.

(Seventh embodiment)
FIG. 16 is a flowchart illustrating a procedure of operation mode setting processing according to the seventh embodiment. The difference of the fuel cell system according to the seventh embodiment from that of the first to sixth embodiments is the processing content of the operation mode setting processing. In addition, the description which overlaps with embodiment mentioned above shall be abbreviate | omitted, and demonstrates below centering on difference.

  Specifically, in step 18 (S18) following step 17, the mode switching unit 45 instructs the integrated control unit 41 to calculate the target generated power Pst and the target rotational speed Rat of the compressor 20. Accordingly, in the integrated control unit 41, the generated power determining unit 41a calculates the target generated power Pst, and the rotational speed determining unit 41d calculates the target rotational speed Rat of the compressor 20 based on the target generated power Pst. .

  In step 19 (S19), the mode switching unit 45 determines whether or not the target rotation speed Rat of the compressor 20 is equal to or higher than the determination rotation speed Ratth. This determination rotational speed Ratth is set by evaluating the uncomfortable feeling given to the driver when the rotational speed of the compressor 20 rises from the stopped state by switching the operation mode from the power generation halt mode to the normal power generation mode. If an affirmative determination is made in step 19, the process proceeds to step 13. On the other hand, if a negative determination is made in step 19, the same determination is made after a predetermined time.

  As described above, in the present embodiment, the controller 40 switches the operation mode from the power generation halt mode to the normal power generation mode when the operating state of the gas supply unit is equal to or higher than the determination operating state during the power generation halt mode. According to such a configuration, since the operation mode is switched from the power generation halt mode to the normal power generation mode before an extreme difference in operating state occurs in the gas supply means, excessive operation noise is generated when the operation mode is switched. Such a situation can be suppressed.

1 is a block diagram showing the overall configuration of a fuel cell system according to a first embodiment. Functional block diagram of the configuration of the controller 40 Flow chart showing the procedure of operation mode setting processing Explanatory drawing which shows the processing concept of integrated control mode Explanatory drawing which shows the calculation process of the extraction current determination part 41b in the integrated control part 41, the valve opening degree determination part 41c, and the rotation speed determination part 41d The flowchart which shows the process sequence of the individual control mode concerning 1st Embodiment. Explanatory drawing of 1st and 2nd target generated electric power P1t, P2t Explanatory drawing which shows the arithmetic processing of the valve opening degree determination part 42b and the rotation speed determination part 42c of the gas supply system control part 42 concerning 2nd Embodiment. The flowchart which shows the process sequence of the individual control mode concerning 3rd Embodiment. Explanatory drawing which shows the arithmetic processing of the valve opening degree determination part 42b and the rotation speed determination part 42c of the gas supply system control part 42 concerning 3rd Embodiment. The flowchart which shows the process sequence of the separate control mode concerning 4th Embodiment. Explanatory drawing of 1st and 2nd target generated electric power P1t, P2t The block diagram which shows the whole structure of the fuel cell system concerning 5th Embodiment. The flowchart which shows the process sequence of the individual control mode concerning 5th Embodiment. The flowchart which shows the process sequence of the individual control mode concerning 6th Embodiment. The flowchart which shows the procedure of the setting process of the operation mode concerning 7th Embodiment.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Fuel cell stack 2 ... Power manager 3 ... Electric motor 4 ... Secondary battery 5 ... Battery controller 6 ... Voltage sensor 7 ... Vehicle speed sensor 8 ... Accelerator opening sensor 10 ... Fuel tank 11 ... Fuel tank original valve 12 ... Pressure reducing valve DESCRIPTION OF SYMBOLS 13 ... Hydrogen pressure regulation valve 14 ... Hydrogen circulation pump 15 ... Purge valve 16 ... Hydrogen diluting device 17 ... Hydrogen pressure sensor 20 ... Compressor 21 ... Air pressure regulation valve 22 ... Air pressure sensor 23 ... Air flow sensor 24 ... Air supply shut-off valve 31 ... Cooling water circulation pump 32 ... Radiator 33 ... Fan 34 ... Cooling water temperature sensor 40 ... Controller 41 ... Integral control unit 41a ... Generated power determination unit 41b ... Extraction current determination unit 41c ... Valve opening degree determination unit 41d ... Rotation speed determination unit 42 ... Gas supply system control unit 42a ... Generated power determination unit 42b ... Valve opening determination unit 42c ... Number of revolutions determination unit 43 ... Extraction current system control unit 43a ... Generated power determination unit 43b ... Extraction current determination unit 44 ... Operation determination unit 45 ... Mode switching unit

Claims (15)

In a fuel cell system mounted on a moving body driven by electric power,
A fuel cell that generates electricity by electrochemically reacting a fuel gas supplied to the fuel electrode and an oxidant gas supplied to the oxidant electrode;
Fuel gas supply means for supplying fuel gas to the fuel electrode of the fuel cell;
An oxidant gas supply means for supplying an oxidant gas to the oxidant electrode of the fuel cell;
A power take-out means for taking out the power obtained in the power generation of the fuel cell and supplying the taken-out power to the mobile body;
Power storage means capable of supplying power stored in the mobile body to the mobile body;
Based on the speed of the moving body, the requested acceleration amount to the moving body, and the state of the power storage means, a target generated power that is a target value of the generated power of the fuel cell is determined, and the determined target power generation Based on electric power, the fuel gas supply means, the oxidant gas supply means, and a control means for controlling the operating state of the power extraction means,
The control means, as a switchable control mode,
After determining a single target generated power, based on the target generated power, the operation state of the fuel gas supply means and the oxidant gas supply means and the operation state of the power extraction means are integratedly controlled. Integrated control mode to
After determining different target generated powers, the operation state of the fuel gas supply means and the oxidant gas supply means is determined based on one target generated power, and the operation of the power extraction means is determined based on the other target generated power. An individual control mode for individually controlling the state ,
In the fuel cell system, as a switchable operation mode, a normal power generation mode in which power is supplied to the mobile body from the power generated by the fuel cell, and the power generation of the fuel cell is stopped to the mobile body. A power generation suspension mode in which electric power is supplied from the electric power stored in the power storage means, and the operation mode is based on the speed of the mobile body, the requested acceleration amount to the mobile body, and the state of the power storage means. Mode switching means for switching between
The control means uses the integrated control mode when the operation mode is the normal power generation mode, uses the individual control mode in a scene where the operation mode is switched from the power generation suspension mode to the normal power generation mode, and then the individual control mode. A fuel cell system that shifts from a control mode to the integrated control mode . The control means controls in advance the operating states of the fuel gas supply means and the oxidant gas supply means in the individual control mode, and the mode switching means switches the operation mode from the power generation halt mode to the normal power generation mode. the fuel cell system of claim 1, when it is determined, characterized in that it starts to control the operating status of the power take-out means that. The control unit is configured to control the operation state of the fuel gas supply unit with respect to target generated power, the operation state of the oxidant gas supply unit with respect to target generated power, and the operation state of the power extraction unit with respect to target generated power. The fuel cell system according to claim 1 or 2 , wherein the fuel cell system performs the calculation corresponding to each of the mode and the individual control mode. In the individual control mode, the control means sets the target generated power so that the operating state of the fuel gas supply means and the oxidant gas supply means is faster than the operating state of the power extraction means. The fuel cell system according to claim 3 , wherein the fuel cell system is determined. In the individual control mode, the control means increases the supply amount of the fuel gas with the operating state of the fuel gas supply means determined based on the target generated power as the upper limit of the withstand pressure range allowed by the system. fuel cell system according to claim 1, any one of 4, characterized in that corrected to. In the individual control mode, the control means increases the fuel gas supply amount, with the operating state of the fuel gas supply means determined based on the target generated power as the upper limit of the maximum operating state allowed by the system. fuel cell system according to claim 1, any one of 5, characterized in that corrected to. In the individual control mode, the control means sets the operating state of the oxidant gas supply means determined on the basis of the target generated power, and the supply amount of the oxidant gas with the upper limit of the pressure resistance allowed for the system as the upper limit. It correct | amends so that it may increase, The fuel cell system as described in any one of Claim 1 to 6 characterized by the above-mentioned. In the individual control mode, the control means sets the operating state of the oxidant gas supply means determined on the basis of the target generated power to the maximum operating state allowed by the system as an upper limit, and the supply amount of oxidant gas is It correct | amends so that it may increase, The fuel cell system as described in any one of Claim 1 to 7 characterized by the above-mentioned. The operating state of the fuel gas supply means determined based on the target generated power so that the supply amount of fuel gas increases as the storable power in the power storage means increases in the individual control mode. is corrected to, so that the supply amount of the oxidizing gas is increased, one of claims 1, wherein the correcting the operating condition of the oxygen-containing gas supply means is determined based on the target generated power 8 A fuel cell system according to claim 1. In the individual control mode, when the operating state of the fuel gas supply unit or the operating state of the oxidant gas supply unit is greater than the determination operating state in the individual control mode, the control unit sets the operating state of the power extraction unit. The fuel cell system according to any one of claims 1 to 9 , wherein control is started. In the individual control mode, when the rate of change of the electric power taken out from the power storage unit is equal to or less than the determination change rate, the control unit determines the fuel gas supply unit that is determined based on the target generated power. Correcting the operating state so that the fuel gas supply amount increases, and correcting the operating state of the oxidant gas supply means determined based on the target generated power so that the oxidant gas supply amount increases. The fuel cell system according to any one of claims 1 to 10 , wherein: An oxidant gas blocking means for blocking oxidant gas supplied to the oxidant electrode of the fuel cell;
In the individual control mode, the control means is a period from the start of the operation state control of the oxidant gas supply means to the start of the operation state control of the power extraction means. The fuel cell system according to claim 2 , wherein the oxidant gas is blocked by the fuel cell system. The control means starts the control of the operation state of the oxidant gas supply means and the operation state of the fuel gas supply means, and then starts the control of the operation state of the power extraction means before starting the control of the operation state of the power extraction means. 3. The fuel cell according to claim 2 , wherein the operating state of the oxidant gas supply unit and the operating state of the fuel gas supply unit are maintained without being reduced even if the acceleration request amount is reduced. system. When the operating state of the oxidant gas supply unit or the operating state of the fuel gas supply unit is equal to or higher than the determination operating state during the power generation suspension mode, the mode switching unit switches the operation mode to power generation suspension. 2. The fuel cell system according to claim 1 , wherein the mode is switched from the mode to the normal power generation mode. In a fuel cell system mounted on a moving body driven by electric power,
A fuel cell that generates electricity by electrochemically reacting a fuel gas supplied to the fuel electrode and an oxidant gas supplied to the oxidant electrode;
Fuel gas supply means for supplying fuel gas to the fuel electrode of the fuel cell;
An oxidant gas supply means for supplying an oxidant gas to the oxidant electrode of the fuel cell;
A power take-out means for taking out the power obtained in the power generation of the fuel cell and supplying the taken-out power to the mobile body;
Power storage means capable of supplying power stored in the mobile body to the mobile body;
As a switchable operation mode, a normal power generation mode in which power is supplied to the mobile body from the power generated by the fuel cell, and the power storage means is configured to stop power generation of the fuel cell and supply power to the mobile body A mode switching means for switching the operation mode based on the speed of the moving body, the requested acceleration amount to the moving body, and the state of the power storage means, ,
Based on the speed of the moving body, the requested acceleration amount to the moving body, and the state of the power storage means, a target generated power that is a target value of the generated power of the fuel cell is determined, and the determined target power generation Based on electric power, the fuel gas supply means, the oxidant gas supply means, and a control means for controlling the operating state of the power extraction means,
The control means, as a switchable control mode,
After determining a single target generated power, based on the target generated power, the operation state of the fuel gas supply means and the oxidant gas supply means and the operation state of the power extraction means are integratedly controlled. Integrated control mode to
After determining different target generated powers, the operation state of the fuel gas supply means and the oxidant gas supply means is determined based on one target generated power, and the operation of the power extraction means is determined based on the other target generated power. It has an individual control mode that controls the state individually,
When the operation mode is the normal power generation mode, the power extraction means is used by using the integrated control mode and using the individual control mode in a scene where the operation mode is switched from the power generation halt mode to the normal power generation mode. The fuel cell system is characterized in that the fuel gas is supplied by the fuel gas supply means and the oxidant gas is supplied by the oxidant gas supply means prior to taking out the electric power.

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