JP2015035339A - Fuel battery system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a fuel battery system for quickly triggering a fuel battery while avoiding arc discharging of a contact point type selector with a simple circuit configuration.SOLUTION: A fuel battery system 1 supplies anode gas and cathode gas to a fuel battery 2 and generates electric power according to a load. The fuel battery system 1 includes a converter 4 which steps up at least one of a voltage on the fuel battery 2 side and a voltage on a battery 3 side, and a contact point type selector 21 which switches the converter 4 and the fuel battery 2 from a shielding state to a connection state when triggering the fuel battery 2. The fuel battery system 1 prevents a current that flows from the converter 4 to the fuel battery 2, and includes a semiconductor type switching element 22 which cuts off connection between the converter 4 and the fuel battery 2.

Description

  The present invention relates to a fuel cell system that controls the voltage of a fuel cell.

  Patent Document 1 discloses a fuel cell system in which a backflow prevention diode is connected between a fuel cell and a converter, and a converter connected between the fuel cell and the battery is controlled to supply power to a load such as a drive motor. It is disclosed. In such a fuel cell system, it is desirable to completely disconnect the fuel cell and the drive motor, etc. when the system is stopped. A contact-type switch that mechanically disconnects the connection between the converter and the fuel cell is used rather than a backflow prevention diode. Provided on the fuel cell side, this switch is shut off when the system is stopped.

JP 2007-159315 A

  In the fuel cell system currently under development, before starting the supply of fuel anode gas and cathode gas, the converter boosts the voltage on the fuel cell side and then switches the contact type switch to the connected state. Then, after the switch is connected, the supply of anode gas and cathode gas to the fuel cell is started to start the fuel cell.

  The reason for starting the gas supply to the fuel cell after the switch is connected is that when the gas supply to the fuel cell is started before the switch is connected, the voltage of the fuel cell rises and the switch is connected This is because the fuel cell voltage is likely to be higher than the converter voltage at this point. When the switch is switched to the connected state in this state, arc discharge occurs at the contact of the switch. As a countermeasure, the gas supply to the fuel cell is awaited until the switch is connected so as not to increase the voltage of the fuel cell.

  However, in such start-up processing, it is necessary to wait for the gas supply to the fuel cell until the switch is switched to the connected state after boosting by the converter, and the rise of the voltage of the fuel cell is delayed. Therefore, there is a problem that the time required for starting the system becomes long.

  An object of the present invention is to provide a fuel cell system that starts a fuel cell quickly while avoiding arc discharge of a contact-type switch with a simple circuit configuration.

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

  One aspect of the fuel cell system according to the present invention is a fuel cell system that supplies anode gas and cathode gas to the fuel cell and generates electric power according to a load. In this fuel cell system, a converter that boosts at least one of the voltage on the fuel cell side and the voltage on the battery side, and when the fuel cell is started, the converter and the fuel cell are switched from a disconnected state to a connected state. Contact type switching device. The fuel cell system includes a semiconductor switch element that blocks a current flowing from the converter to the fuel cell and disconnects the connection between the converter and the fuel cell.

  According to this aspect, the fuel cell system is provided with the semiconductor-type switch element between the converter and the fuel cell, and the switch element prevents a current flowing from the converter to the fuel cell, and the converter and the fuel cell. Disconnect from the.

  As a result, for example, even if the contact type switching device is switched to the connected state immediately after starting the fuel cell system, the current flowing to the switching device can be interrupted in advance by the switch element, so that arc discharge occurs when the switching device is connected. Can be avoided.

  And even if the switch element is switched to the connected state when the switch is in the connected state, the switch is in the connected state, so arc discharge does not occur at the contact of the switch, and the switch element is a semiconductor element, so the switch element As such, arcing does not occur.

  Therefore, the switch can be switched to the connected state immediately after starting without causing arc discharge, and gas supply to the fuel cell can be performed promptly.

  Therefore, the fuel cell can be started quickly while avoiding arc discharge with a simple circuit configuration.

FIG. 1 is a configuration diagram showing a fuel cell system according to an embodiment of the present invention. FIG. 2 is a timing chart regarding a general activation process. FIG. 3 is a timing chart regarding the activation process in the present embodiment. FIG. 4 is a flowchart showing a method for controlling the reverse blocking switch element.

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

  FIG. 1 is a block diagram showing a configuration of a fuel cell system in an embodiment of the present invention.

  The fuel cell system 1 is, for example, a power supply system mounted on an electric vehicle that drives a vehicle with a three-phase AC drive motor 6.

  The fuel cell system 1 includes a fuel cell stack 2, a high-power battery 3, a PM (Power Management) circuit 4, an auxiliary motor 5, and a controller 7. The fuel cell system 1 includes a stack circuit breaker 21, a battery circuit breaker 31, an auxiliary inverter 51, a drive inverter 61, a gas supply / discharge device 200, and a cell voltage measurement device 300.

  The fuel cell stack 2 is a power source for the auxiliary motor 5 and the drive motor 6. The fuel cell stack 2 generates power according to loads such as the auxiliary motor and the drive motor 6. The fuel cell stack 2 is a stack of fuel cells of a plurality of battery cells.

  In a fuel cell, an electrolyte membrane is sandwiched between an anode electrode (fuel electrode) and a cathode electrode (oxidant electrode), an anode gas containing hydrogen in the anode electrode (fuel gas), and a cathode gas containing oxygen in the cathode electrode (fuel gas). Electric power is generated by supplying an oxidant gas) from the outside. The electrode reaction (power generation reaction) that proceeds in both the anode electrode and the cathode electrode is as follows.

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

  The fuel cell generates an electromotive force of about 1 volt by the electrode reactions (1) and (2).

  When a fuel cell is used as a power source for an automobile, the power required to drive the drive motor 6 increases as the amount of depression of the accelerator pedal increases. Therefore, it is necessary to stack several hundred fuel cells. is there.

  Since the fuel cells stacked on the fuel cell stack 2 are connected to each other in series, the sum of the cell voltages generated in each fuel cell becomes the output voltage of the fuel cell stack 2. The fuel cell stack 2 is connected to each of the drive inverter 61 and the voltage terminal 4 a of the PM circuit 4 via the stack circuit breaker 21.

  The stack circuit breaker 21 is a contact-type switch that mechanically interrupts the fuel cell stack 2 from the drive inverter 61 and the PM circuit 4. The stack circuit breaker 21 enables the fuel cell stack 2 to be completely disconnected from the drive inverter 61 and the PM circuit 4 during an emergency stop or the like. The stack breaker 21 is controlled by the controller 7.

  The stack circuit breaker 21 connects the fuel cell stack 2 to the drive inverter 61 and the PM circuit 4 by the controller 7 when the fuel cell stack 2 is activated. That is, when the fuel cell stack 2 is started, the stack circuit breaker 21 switches between the fuel cell stack 2 and the PM circuit 4 from the disconnected state to the connected state.

  The stack breaker 21 connects the positive terminal (+) of the fuel cell stack 2 to the voltage terminal 4 a on the positive side of the PM circuit 4, and connects the negative terminal (−) of the fuel cell stack 2 to the negative side of the PM circuit 4. Connect to voltage terminal 4a.

  The high-power battery 3 is connected to the auxiliary inverter 51 and the PM circuit 4 via the battery breaker 31. The high-power battery 3 is, for example, a 300 V (volt) lithium ion battery. The high-power battery 3 stores regenerative power generated by the drive motor 6 by the PM circuit 4. The high power battery 3 is connected to each of the auxiliary inverter 51 and the voltage terminal 4 b of the PM circuit 4 by the battery circuit breaker 31.

  The battery circuit breaker 31 is a contact-type switch that mechanically interrupts the high-power battery 3 from the auxiliary inverter 51 and the PM circuit 4. The battery breaker 31 is controlled by the controller 7. For example, when the fuel cell system 1 is stopped, the battery circuit breaker 31 disconnects the high-power battery 3 from the auxiliary inverter 51 and the PM circuit 4, and connects the high-power battery 3 to the auxiliary inverter 51 and the PM circuit 4 at the time of startup. .

  The battery breaker 31 connects the positive terminal (+) of the high-power battery 3 to the positive-side voltage terminal 4 b of the PM circuit 4, and connects the negative terminal (−) of the high-power battery 3 to the negative-side voltage terminal of the PM circuit 4. Connect to 4b.

  The PM circuit 4 is a converter that boosts at least one of the voltage on the fuel cell stack 2 side and the voltage on the high-power battery 3 side. The PM circuit 4 is a so-called bidirectional buck-boost circuit.

  The PM circuit 4 includes a reactor 41, a stack side capacitor 42, a battery side capacitor 43, and switching elements 44a to 44d. Each of the switching elements 44a to 44d has a diode connected in parallel. The diodes are arranged so that the direction in which current flows through the switching elements 44a to 44d and the forward direction of the diodes are reversed.

  The switching elements 44 a to 44 d are on / off controlled by the controller 7. The voltage generated in the stack side capacitor 42 is stepped up / down by the on / off control of the switching elements 44a to 44d. Further, the voltage of the battery-side capacitor 43 can be boosted or lowered by on / off control of the switching elements 44a to 44d.

  The auxiliary motor 5 is connected in parallel between the voltage terminal 4 b of the PM circuit 4 and the battery breaker 31. In this embodiment, the auxiliary motor 5 drives the compressor 212 that supplies the cathode gas to the fuel cell stack 2.

  The auxiliary inverter 51 converts the DC voltage supplied from the fuel cell stack 2 by the PM circuit 4 into an AC voltage, and supplies the AC voltage to the auxiliary motor 5.

  The drive inverter 61 is connected in parallel between the stack circuit breaker 21 and the voltage terminal 4 a of the PM circuit 4. The drive inverter 61 converts the voltage supplied from the fuel cell stack 2 by the PM circuit 4 into an AC voltage, and supplies the AC voltage to the drive motor 6.

  The gas supply / discharge device 200 is a device that supplies anode gas and cathode gas to the fuel cell stack 2, and dilutes and discharges the anode off-gas discharged from the fuel cell stack 2 with the cathode off-gas.

  The gas supply / discharge device 200 includes a cathode gas supply passage 211, a compressor 212, a discharge passage 213, a pressure regulating valve 214, an anode gas supply passage 221, a high pressure tank 222, a pressure regulating valve 223, a discharge passage 224, A purge valve 225.

  The cathode gas supply passage 211 is a passage through which the cathode gas supplied to the fuel cell stack 2 flows. The cathode gas supply passage 211 has one end communicating with the outside air and the other end connected to the cathode gas inlet hole of the fuel cell stack 2.

  The compressor 212 is provided in the cathode gas supply passage 211. The compressor 212 takes air (outside air) as cathode gas into the cathode gas supply passage 211 and supplies the air to the fuel cell stack 2.

  The discharge passage 213 is a passage through which the cathode off gas discharged from the fuel cell stack 2 flows. One end of the discharge passage 213 is connected to the cathode gas outlet hole of the fuel cell stack 2, and the other end is an open end. A pressure regulating valve 214 is provided in the discharge passage 213.

  The anode gas supply passage 221 is a passage for supplying anode gas from the high-pressure tank 222 to the fuel cell stack 2. One end of the anode gas supply passage 221 is connected to the high-pressure tank 222, and the other end is connected to the anode gas inlet hole of the fuel cell stack 2. In the high-pressure tank 222, anode gas is stored in a high-pressure state.

  The pressure regulating valve 223 is provided in the anode gas supply passage 221. The pressure regulating valve 223 adjusts the anode gas discharged from the high-pressure tank 222 to a desired pressure and supplies it to the fuel cell stack 2. The pressure regulating valve 223 is an electromagnetic valve whose opening degree can be adjusted continuously or stepwise, and the opening degree is controlled by the controller 7.

  The discharge passage 224 is a passage through which the anode off gas discharged from the fuel cell stack 2 flows. One end of the discharge passage 224 is connected to the anode gas outlet hole of the fuel cell stack 2, and the other end joins the cathode gas discharge passage 213.

  In the discharge passage 224, a mixed gas (hereinafter referred to as “anode”) of excess anode gas that has not been used for the electrode reaction and impure gas that has cross-leaked from the cathode gas passage in the fuel cell stack 2 to the anode gas passage. Off-gas ") is discharged. The impurity gas is nitrogen contained in air, water vapor accompanying power generation, or the like.

  A buffer tank is formed in the discharge passage 224 upstream of the purge valve 225, and the anode off gas flowing from the fuel cell stack 2 is temporarily stored in the buffer tank. A part of the water vapor in the anode off-gas is condensed in the buffer tank to become liquid water and separated from the anode off-gas.

  The purge valve 225 is provided in the discharge passage 224. The purge valve 225 is an electromagnetic valve whose opening degree can be adjusted continuously or stepwise, and the opening degree is controlled by the controller 7. By adjusting the opening of the purge valve 225, the flow rate of the anode off-gas discharged from the buffer tank can be adjusted, and the anode gas concentration in the buffer tank can be kept below a certain level.

  The voltage measuring device 300 measures the cell voltage of each battery cell stacked on the fuel cell stack 2. A plurality of voltage lines connected to the positive terminal of each battery cell are connected to the voltage measuring device 300. The voltage measuring apparatus 300 measures the cell voltage of each battery cell and the total voltage of the sum of each battery cell, and supplies these measurement results to the controller 7.

  In this way, the gas supply / discharge device 200 supplies the anode gas and the cathode gas to the fuel cell stack 2 to generate power in the fuel cell stack 2.

  The controller 7 includes a microcomputer having a central processing unit (CPU), a read only memory (ROM), a random access memory (RAM), and an input / output interface (I / O interface).

  Signals are input to the controller 7 from various sensors that detect the state of the fuel cell system 1. Various sensors include a key sensor 71 that detects a start request and a stop request of the fuel cell system 1 based on on / off switching of the start key, a current sensor 72 that detects an output current taken out from the fuel cell stack 2, and a depression of an accelerator pedal. There is an accelerator stroke sensor 73 for detecting the amount.

  The controller 7 calculates a target value (hereinafter referred to as “target current”) of a current to be extracted from the fuel cell stack 2 based on loads such as the auxiliary motor 5 and the drive motor 6 connected to the fuel cell stack 2.

  For example, the controller 7 calculates the target current having a large value because the required power necessary for driving the drive motor 6 increases as the amount of depression of the accelerator pedal increases.

  The controller 7 calculates target values of the anode gas pressure and the cathode gas pressure based on the target current, and controls the gas supply / discharge device 200 based on the calculation result. At the same time, the controller 7 identifies the target voltage corresponding to the target current with reference to the reference characteristics of the fuel cell stack 2, and generates a PWM (pulse width modulation) signal so that the voltage of the stack side capacitor 42 becomes the target voltage. And supplied to the switching elements 44a to 44d. Thus, the operation of the fuel cell stack 2 is performed by the controller 7. When the controller 7 receives a stop request for the fuel cell system 1, the controller 7 stops the operation of the fuel cell stack 2.

  When the controller 7 receives a start request for the fuel cell system 1, the controller 7 executes the start-up process of the fuel cell stack 2 and controls the PM circuit 4 to supply the generated power of the fuel cell stack 2 to the auxiliary motor 5. . Here, a general startup processing method of the fuel cell system 1 will be briefly described.

  FIG. 2 is a timing chart showing a startup process of a general fuel cell system 1.

  First, the operation of the fuel cell stack 2 is stopped by a stop request before time t0. In the stop process, the supply of the anode gas and the cathode gas by the gas supply / discharge device 200 is stopped, and each of the stack circuit breaker 21 and the battery circuit breaker 31 is switched from the connected state to the disconnected state. As a result, the voltage of the stack side capacitor 42 is reduced to 0V.

  When the fuel cell system 1 is activated at time t0, the activation process of the high-power battery 3 is performed. In the starting process of the high-power battery 3, in order to confirm that the high-power battery 3 is normal, for example, it is determined whether or not the state of the high-power battery 3 such as voltage and temperature exceeds a predetermined threshold value. Then, when it is determined that the state of the high-power battery 3 exceeds a predetermined threshold, the battery breaker 31 is switched from the disconnected state to the connected state.

  At time t1, on / off control of the switching elements 44a to 44d is executed in the PM circuit 4, so that the voltage of the stack side capacitor 42 becomes the upper limit voltage value depending on the voltage of the high voltage battery 3 as shown in FIG. The pressure is increased to. The upper limit voltage value is determined by the withstand voltage limit value of the drive inverter 61.

  By setting the voltage of the stack side capacitor 42 to the upper limit voltage value, the voltage of the fuel cell stack 2 is limited to the upper limit voltage value, so that the drive inverter 61 can be protected from an excessive voltage. Further, by increasing the voltage of the stack side capacitor 42 to the upper limit voltage value, current flowing from the fuel cell stack 2 to the PM circuit 4 via the stack circuit breaker 21 is suppressed, and arc discharge occurs when the stack circuit breaker 21 is connected. Prevent it from occurring.

  At time t2, when the voltage of the stack side capacitor 42 rises to the upper limit voltage value, as shown in FIG. 2B, the setting of the stack circuit breaker 21 is switched from the cut-off state to the connected state.

  Then, as shown in FIG. 2C, after waiting until the stack circuit breaker 21 is switched from the cut-off state to the connected state, the pressure regulating valve 223 of the gas supply / discharge device 200 is opened at time t3, so that the anode gas becomes the fuel. The battery stack 2 is supplied.

  As the anode gas is supplied to the fuel cell stack 2, the electrode reactions (1) and (2) described above occur in the fuel cell stack 2, and the voltage of the fuel cell stack 2 is changed as shown in FIG. To rise. The increased voltage is transiently increased from the voltage of the stack side capacitor 42 and then limited to the upper limit voltage value. Thereby, the drive inverter 61 is protected from an excessive voltage.

  Thereafter, as the supply pressure of the anode gas increases, as shown in FIG. 2 (e), a current taken out from the fuel cell stack 2 is output to the auxiliary inverter 51 via the PM circuit 4.

  At time t4, as shown in FIG. 2C, the supply pressure of the anode gas rises to the target value, and the output current of the fuel cell stack 2 rises to a current value necessary for driving the auxiliary motor 5 accordingly. To do. In this way, the supply of the anode gas to the fuel cell stack 2 is completed.

  As described above, in a general startup process of the fuel cell system 1, the voltage of the stack side capacitor 42 of the PM circuit 4 is raised to the upper limit voltage value before supplying the anode gas to the fuel cell stack 2. Thereafter, the stack circuit breaker 21 is switched to the connected state at time t2, and the supply of anode gas is started at time t3 to start the fuel cell stack 2.

  The reason why the gas supply is started after the stack circuit breaker 21 is connected is that if the gas supply is started before the stack circuit breaker 21 is connected, the voltage of the fuel cell stack 2 becomes PM when the stack circuit breaker 21 is connected. This is because there is a concern that the voltage is higher than the voltage of the circuit 4.

  If the stack circuit breaker 21 is switched to the connected state while the voltage of the fuel cell stack 2 is higher than the voltage of the stack side capacitor 42 of the PM circuit 4, arc discharge occurs at the contact of the stack circuit breaker 21. As a countermeasure, the supply of anode gas is waited until the stack circuit breaker 21 is switched to the connected state so that the voltage of the fuel cell stack 2 does not become higher than the voltage of the stack side capacitor 42.

  However, in such start-up processing, gas supply to the fuel cell stack 2 is not performed until the stack circuit breaker 21 is switched to the connected state after the PM circuit 4 starts increasing the voltage of the stack side capacitor 42. have to wait. As a result, the time from when the fuel cell system 1 is activated to when the voltage of the fuel cell stack 2 is raised is delayed, and the activation of the fuel cell stack 2 is delayed.

  Therefore, in the present embodiment, in order to quickly start the fuel cell stack 2 while avoiding arc discharge in the stack circuit breaker 21, the connection line 20 connecting the fuel cell stack 2 and the PM circuit 4 is A reverse blocking switch element 22 is provided.

  The reverse blocking switch element 22 is connected between the stack circuit breaker 21 and the voltage terminal 4 a of the PM circuit 4. The reverse blocking type switch element 22 prevents a current flowing from either the PM circuit 4 or the drive inverter 61 to the fuel cell stack 2 and switches the PM circuit 4 and the fuel cell stack 2 from a disconnected state to a connected state. This is a switch element of the formula.

  The reverse blocking switch element 22 blocks forward current flowing from the fuel cell stack 2 to the stack breaker 21 in accordance with a control signal from the controller 7.

  Further, the reverse blocking switch element 22 also serves as a backflow prevention diode. For example, when a current taken out from the high voltage battery 3 is supplied to the drive inverter 61 via the PM circuit 4, a current that flows backward from the PM circuit 4 to the fuel cell stack 2 is blocked by the reverse blocking switch element 22. .

  Alternatively, when the current regenerated by the drive motor 6 during braking of the vehicle is supplied to the high-power battery 3 via the PM circuit 4 by the reverse blocking switch element 22, the current flows backward from the drive inverter 61 to the fuel cell stack 2. Current is blocked.

  In the present embodiment, the reverse blocking switch element 22 is a reverse blocking IGBT (Insulated Gate Bipolar Transistor). In the reverse blocking switch element 22, the emitter terminal is connected to the stack circuit breaker 21 in the connection line 20, the collector terminal is connected to the voltage terminal 4 a of the PM circuit 4, and the gate (control) terminal is connected to the controller 7. .

  For example, the controller 7 supplies an H (High) level control signal to the gate terminal of the reverse blocking switch element 22 to increase the internal resistance value between the emitter terminal and the collector terminal, thereby increasing the distance between the terminals. Set to non-conducting state (blocking state). The controller 7 supplies an L (Low) level control signal to the gate terminal, thereby reducing the internal resistance value between the emitter terminal and the collector terminal and bringing the terminals into a conductive state (connected state).

  In the present embodiment, when the controller 7 receives an activation request from the key sensor 71 in the activation process of the fuel cell system 1, the controller 7 sets the stack breaker 21 to the connected state, and then connects the reverse blocking switch element 22 from the interrupted state. Switch to state.

  FIG. 3 is a timing chart showing an example of a startup process by the controller 7 in the present embodiment.

  FIG. 3A is a diagram showing a switching state of the reverse blocking switch element 22. FIG. 3B is a diagram illustrating a change in the voltage of the stack side capacitor 42 of the PM circuit 4. FIG. 3C is a diagram showing a switching state of the stack circuit breaker 21. FIG. 3D is a diagram showing a change in the pressure of the anode gas supplied from the pressure regulating valve 223 to the fuel cell stack 2.

  FIG. 3E is a diagram showing a change in the output voltage taken out from the fuel cell stack 2. FIG. 3F is a diagram showing a change in the output current of the fuel cell stack 2. The horizontal axis of each drawing from FIG. 3A to FIG. 3E is a common time axis.

  First, before the time t10, the stop process of the fuel cell system 1 is performed by the stop request.

  In the stop process, the controller 7 controls the gas supply / discharge device 200 to stop the supply of the anode gas and the cathode gas. Specifically, the controller 7 closes each of the pressure regulating valve 223 and the purge valve 225 and stops driving the compressor 212. The controller 7 switches each of the stack circuit breaker 21 and the battery circuit breaker 31 from the connected state to the disconnected state. Along with this, the voltage of the stack side capacitor 42 decreases to 0V. Furthermore, the controller 7 switches the reverse blocking switch element 22 from the connected state (ON) to the cut-off state (OFF).

  At time t <b> 10, when the controller 7 receives a request for starting the fuel cell system 1 from the key sensor 71, the controller 7 starts the startup process of the fuel cell system 1. In the activation process, the controller 7 confirms that the high-power battery 3 is normal and switches the setting of the battery breaker 31 from the disconnected state to the connected state. Thereby, as shown in FIG.3 (b), the voltage of the high voltage battery 3 is supplied to the PM circuit 4, and the starting process of the high voltage battery 3 is completed.

  When the start-up process of the fuel cell system 1 is started, the controller 7 switches the setting of the stack circuit breaker 21 from the disconnected state to the connected state and opens the pressure regulating valve 223 as shown in FIG. By opening the pressure regulating valve 223, the supply pressure of the anode gas increases as shown in FIG. Note that the pressure regulating valve 223 may be opened after a predetermined time elapses after the setting of the stack circuit breaker 21 is switched to the connected state until the stack circuit breaker 21 actually enters the connected state.

  As the anode gas supply pressure increases, an electrode reaction occurs in the fuel cell stack 2, and the voltage of the fuel cell stack 2 becomes higher than the voltage of the stack side capacitor 42 as shown in FIG. Even in such a situation, since the reverse blocking switch element 22 is in the cut-off state, the forward current flowing from the fuel cell stack 2 to the stack-side capacitor 42 is cut off. For this reason, since the fuel cell stack 2 is in a no-load state, the open circuit voltage of the fuel cell stack 2 rises to the maximum value MAX.

  At time t11, the controller 7 supplies a PWM signal for increasing the voltage of the stack side capacitor 42 to the upper limit voltage value to the switching elements 44a to 44d, thereby controlling the switching elements 44a to 44d on and off. Since the current supplied from the high-power battery 3 to the battery-side capacitor 43 is accumulated in the stack-side capacitor 42 by the on / off control of the switching elements 44a to 44d, the voltage of the stack-side capacitor 42 is shown in FIG. Rises.

  Immediately before time t12, as shown in FIGS. 3B and 3E, the open circuit voltage of the fuel cell stack 2 is higher than the voltage of the stack side capacitor.

  At time t12, the controller 7 switches the reverse blocking switch element 22 from OFF to ON as shown in FIG. As a result, the fuel cell stack 2 is connected to the stack side capacitor 42 via the stack circuit breaker 21, and a large current (charge) is transferred from the fuel cell stack 2 to the stack side capacitor 42 as shown in FIG. Supplied (accumulated).

  At time t12 when the reverse blocking switch element 22 is switched to ON, the stack circuit breaker 21 is already in a connected state, so that no arc discharge occurs at the contact point of the stack circuit breaker 21. Further, since the reverse blocking switch element 22 is a semiconductor element, arc discharge does not occur in the reverse blocking switch element 22 itself when the reverse blocking switch element 22 is set to ON.

  Further, as the electric charge is accumulated from the fuel cell stack 2 to the stack side capacitor 42, as shown in FIG. 3B, the voltage of the stack side capacitor 42 rapidly increases. The voltage of the stack side capacitor 42 is limited to the upper limit voltage value for protecting the drive inverter 61 by the on / off control of the switching elements 44a to 44d.

  Further, since the fuel cell stack 2 is connected to the stack-side capacitor 42 by switching the reverse blocking switch element 22 to ON, as shown in FIG. Decreases to voltage value. Along with this, the output current of the fuel cell stack 2 is supplied to the auxiliary inverter 51 via the PM circuit 4.

  At time t13, the output current of the fuel cell stack 2 is supplied to the auxiliary machine inverter 51 via the PM circuit 4, so that the current value necessary for driving the auxiliary machine motor 5 as shown in FIG. That is, it rises to the target value. As a result, the cathode gas is supplied from the compressor 212 to the fuel cell stack 2, and the start-up process of the fuel cell stack 2 is completed. Note that before the supply of the anode gas is completed, power may be supplied from the high voltage battery 3 to the auxiliary motor 5 and the cathode gas may be supplied from the compressor 212 to the fuel cell stack 2.

  Thus, the controller 7 immediately connects the stack circuit breaker 21 to the connected state after the start-up process of the fuel cell system 1 is started, and supplies the anode gas to the fuel cell stack 2 by the gas supply / discharge device 200. Thereafter, the controller 7 switches the reverse blocking switch element 22 to ON. At time t12, the output voltage of the fuel cell stack 2 is higher than the stack side voltage of the PM circuit 4 with the supply of the anode gas. However, since the stack breaker 21 is already connected, the stack breaker 21 Arc discharge does not occur even if current flows through the contact.

  Therefore, even if the stack circuit breaker 21 is connected and the anode gas as fuel is supplied to the fuel cell stack 2 immediately after the fuel cell system 1 is started, the fuel cell stack 2 can be connected to the stack side capacitor without causing arc discharge. 42 can be connected.

  Next, details of the switching method of the reverse blocking switch element 22 will be described.

  FIG. 4 is a flowchart showing an example of the processing procedure of the startup processing method of the fuel cell system 1 by the controller 7.

  First, in step S901, when the controller 7 receives a start request from the key sensor 71, the controller 7 sets the reverse blocking switch element 22 to OFF.

  As a result, the fuel cell stack 2 is disconnected from the PM circuit 4 and the drive inverter 61, so that the current from the fuel cell stack 2 to the stack breaker 21 is interrupted.

  In addition, even if the supply of anode gas to the fuel cell stack 2 is started, no current is forcibly taken out from the fuel cell stack 2, so that it is possible to prevent the anode gas from being deficient and the electrolyte membrane from deteriorating. Furthermore, even if the reverse blocking switch element 22 is not turned OFF and remains ON at the previous stop, the reverse blocking switch element 22 can be reliably turned OFF at the time of startup.

  In step S902, the controller 7 sets the stack breaker 21 from the interrupted state to the connected state as shown at time t10 in FIG.

  In step S903, the controller 7 opens the pressure regulating valve 223 and supplies the anode gas to the fuel cell stack 2 as shown at time t10 in FIG. As a result, power generation is started in the fuel cell stack 2 as shown at time t10 in FIG.

  In step S <b> 904, the controller 7 increases the voltage of the stack side capacitor 42 of the PM circuit 4 to the upper limit voltage value of the drive inverter 61. Note that the processing in step S904 may be performed in parallel with the processing in steps S902 and S903, or the processing in step S904 may be performed before the processing in steps S902 and S903.

  Next, in steps S905 and S906, it is determined whether or not the supply of the anode gas to the fuel cell stack 2 is completed.

  In step S905, the controller 7 determines whether or not the total voltage of the fuel cell stack 2 exceeds a predetermined stack threshold value. The total voltage is an integrated value of cell voltages generated in the fuel cells stacked on the fuel cell stack 2. Further, as the stack threshold value, for example, the voltage value of the fuel cell stack 2 when the IV characteristic recovers to 90% with respect to the reference characteristic defined by the IV characteristic of the fuel cell stack 2 during normal operation is used.

  The controller 7 repeats the process of step S905 until the total voltage of the fuel cell stack 2 exceeds the stack threshold.

  In step S906, when the total voltage of the fuel cell stack 2 exceeds the stack threshold value, the controller 7 determines whether or not the degree of variation in the cell voltage of each fuel cell stacked in the fuel cell stack 2 is small. If the controller 7 determines that the variation degree of each cell voltage is small, the controller 7 proceeds to step S907. On the other hand, if the controller 7 determines that the variation degree of each cell voltage is large, the controller 7 returns to step S905.

  Here, a method for determining the degree of variation will be briefly described. Immediately after the anode gas is supplied to the fuel cell stack 2, the anode gas may not be evenly distributed to all the fuel cells, and there is a fuel cell having a low concentration of the anode gas. The cell voltage of a fuel cell having a low anode gas concentration is lower than the cell voltage of other fuel cells. For this reason, it is possible to determine whether or not the anode gas is uniformly supplied to each fuel cell in the fuel cell stack 2 by obtaining the degree of variation in the cell voltage of each fuel cell.

  For example, the controller 7 calculates the maximum value, minimum value, and average value of each cell voltage, and both the difference obtained by subtracting the average value from the maximum value and the difference obtained by subtracting the minimum value from the average value are less than a predetermined value. In some cases, it is determined that the degree of variation is small. Alternatively, the controller 7 calculates a deviation value of each cell voltage, and determines that the degree of variation is small when the deviation value is within a predetermined range.

  As described above, the controller 7 completes the supply of the anode gas when the total voltage of the fuel cell stack 2 is larger than the stack threshold and the degree of variation in the cell voltage of each fuel cell in the fuel cell stack 2 is small. It is determined that

  If it is determined in step S907 that the supply of the anode gas is completed, the controller 7 switches the reverse blocking switch element 22 from OFF to ON as shown at time t12 in FIG.

  As a result, as shown in FIG. 3 (f), the output current extracted from the fuel cell stack 2 is supplied to the auxiliary inverter 51 via the PM circuit 4. The auxiliary motor 5 is driven by the current from the auxiliary inverter 51 and the cathode gas is supplied from the compressor 212 to the fuel cell stack 2.

  Further, when current is taken out from the fuel cell stack 2 immediately after the supply of the anode gas is completed, the hydrogen concentration of the anode gas is locally insufficient in the fuel cell stack 2 as the anode gas is consumed. The electrolyte membrane may deteriorate. As a countermeasure, in steps S908 and S909, the controller 7 monitors the supply state of the anode gas in the fuel cell stack 2 after setting the reverse blocking switch element 22 to ON.

  In step S908, the controller 7 determines whether or not the total voltage of the fuel cell stack 2 exceeds the stack threshold, similarly to step S905.

  If the total voltage has not decreased below the stack threshold value in step S909, the controller 7 determines whether or not the degree of variation in cell voltage is small, as in step S906.

  If the total voltage has not dropped below the stack threshold and the degree of variation in cell voltage has not increased, the controller 7 proceeds to step S910.

  On the other hand, in step S911, the controller 7 switches the reverse blocking switch element 22 to OFF when the total voltage has dropped below the stack threshold or when the degree of variation in the cell voltage has increased, step S905 is performed. Return to. Then, until the state where the anode gas is insufficient in the fuel cell stack 2 is resolved, the reverse blocking switch element 22 is turned off to suppress consumption of the anode gas. As a result, the fuel cell can be prevented from deteriorating due to the lack of anode gas.

  In step S910, the controller 7 determines whether or not a predetermined time has elapsed since turning on the reverse blocking switch element 22. If the predetermined time has not elapsed, the controller 7 returns to step S908 and repeats a series of processes. And the controller 7 complete | finishes the starting process method of the fuel cell system 1, when predetermined time passes.

  According to the embodiment of the present invention, one of the voltage terminals 4a is connected to the fuel cell stack 2, and the other voltage terminal 4b is connected to the high voltage battery 3 by the PM circuit 4 so that the voltage terminals 4a and 4b are At least one is boosted. The stack breaker 21 switches the connection line 20 between the PM circuit 4 and the fuel cell stack 2 from the cut-off state to the connected state when the fuel cell stack 2 is started.

  In the fuel cell system 1 including the PM circuit 4 and the stack circuit breaker 21, the reverse blocking switch element 22 is connected to the connection line 20 between the PM circuit 4 and the fuel cell stack 2. The reverse blocking switch element 22 blocks a current flowing backward from the PM circuit 4 to the fuel cell stack 2 and blocks the connection line 20 between the PM circuit 4 and the fuel cell stack 2.

  Thus, for example, even if the stack circuit breaker 21 is switched to the connected state immediately after the fuel cell system 1 is started, the forward current flowing through the stack circuit breaker 21 is blocked in advance by the reverse blocking switch element 22. Is possible. For this reason, even if the stack circuit breaker 21 is connected, it is possible to avoid the occurrence of arc discharge.

  Even if the reverse blocking type switch element 22 is switched to ON when the stack breaker 21 is in the connected state, the stack breaker 21 is in the connected state, so that no arc discharge occurs at the contact point of the stack breaker 21. . Further, since the reverse blocking switch element 22 is a semiconductor element, no arc discharge occurs in the reverse blocking switch element 22 itself when the reverse blocking switch element 22 is switched to ON.

  Therefore, the reverse blocking type switch element 22 makes it possible to switch the stack circuit breaker 21 to the connected state immediately after startup without generating arc discharge, so that supply of anode gas is started immediately after startup. Can do.

  Therefore, in the fuel cell system 1, the fuel cell stack 2 can be started quickly while avoiding arc discharge with a simple circuit configuration. In the present embodiment, the reverse blocking switch element 22 is connected to the connection line 20 between the stack circuit breaker 21 and the voltage terminal 4 a of the PM circuit 4, but between the fuel cell stack 2 and the stack circuit breaker 21. Even if it is connected to the connection line 20, the same effect can be obtained.

  Moreover, in this embodiment, as shown in FIG.3 (c), the controller 7 interrupts | blocks the setting of the reverse blocking type | mold switch element 22 immediately after making the stack circuit breaker 21 into a connection state at the time of starting of the fuel cell system 1. FIG. Switch from to connected state.

  As a result, the anode gas can be supplied to the fuel cell stack 2 simultaneously with the startup of the fuel cell system 1, so that the timing for completing the startup of the fuel cell stack 2 can be further advanced.

  Moreover, when starting the fuel cell system 1, the controller 7 sets the reverse blocking type switch element 22 to OFF and then switches the stack breaker 21 to the connected state.

  For example, it is conceivable that after the fuel cell system 1 is stopped, the fuel cell stack 2 is restarted before the output voltage of the fuel cell stack 2 drops to near 0V. In this case, if the stack circuit breaker 21 is connected immediately after the fuel cell system 1 is started, a current may flow from the fuel cell stack 2 to the stack circuit breaker 21 to cause arc discharge. As a countermeasure, the reverse blocking switch element 22 is set to OFF before the stack circuit breaker 21 is switched to the connected state.

  Further, when any abnormality occurs in the system components (for example, the voltage of the fuel cell stack 2 falls below the fail threshold), the emergency stop is performed to protect the system. During an emergency stop, a discharge process that lowers the output voltage of the fuel cell stack 2 that is executed in a normal stop process is often not performed.

  Therefore, after the emergency stop of the fuel cell system 1, the fuel cell stack 2 may be restarted before the output voltage of the fuel cell stack 2 decreases. In this case, the output voltage of the fuel cell stack 2 is It may be higher than the voltage of the side capacitor 42. Therefore, the controller 7 also switches the stack circuit breaker 21 to the connected state after setting the reverse blocking switch element 22 to OFF even when the fuel cell system 1 is restarted after an emergency stop.

  Thereby, even if the fuel cell system 1 is restarted while the reverse blocking switch element 22 is ON due to an emergency stop or the like, the stack breaker 21 is brought into the connected state after the reverse blocking switch element 22 is turned OFF. The occurrence of arc discharge can be prevented.

  In the present embodiment, the controller 7 supplies the anode gas to the fuel cell stack 2 by the gas supply / discharge device 200 in order to start the fuel cell stack 2 after setting the reverse blocking switch element 22 to OFF. At the same time, the controller 7 may control the PM circuit 4 to protect the drive inverter 61 to increase the voltage at the voltage terminal 4a on the fuel cell stack 2 side to a predetermined upper limit voltage value.

  As described above, by executing the start-up process of the fuel cell stack 2 and the boost control of the voltage terminal 4a of the PM circuit 4 in parallel, the timing for switching the reverse blocking switch element 22 to ON can be advanced. Therefore, the startup process of the fuel cell stack 2 can be completed earlier.

  Further, in this embodiment, when the controller 7 determines that the total voltage of the fuel cell stack 2 exceeds a predetermined stack threshold, the controller 7 sets the reverse blocking switch element 22 to the connected state. The stack threshold is determined based on, for example, the voltage value of the fuel cell stack 2 when the anode gas is sufficiently supplied to the fuel cell stack 2.

  As a result, it is possible to prevent the anode gas from being deficient due to the electrode reaction in the fuel cell stack 2 as current is supplied from the fuel cell stack 2 to the auxiliary motor 5, and the electrolyte membrane is deteriorated due to the lack of anode gas. Can be suppressed.

  Further, in the present embodiment, the controller 7 reverse-switching type switching element 22 when the total voltage of the fuel cell stack 2 is larger than the stack threshold value and the variation degree of the cell voltage of each fuel cell is smaller than a predetermined value. Set to connected state.

  Thus, in addition to confirming the total voltage of the fuel cell stack 2, by confirming the degree of variation in the cell voltage, the anode gas is depleted in some fuel cells of the fuel cell stack 2, and the electrolyte membrane Deterioration can be avoided.

  In the present embodiment, the controller 7 determines whether the total voltage of the fuel cell stack 2 or the degree of variation of each cell voltage has decreased below a predetermined threshold until a predetermined period has elapsed since the reverse blocking switch element 22 was turned on. Confirm whether or not. The controller 7 switches the reverse blocking switch element 22 to OFF when either one of the total voltage and the variation degree of each cell voltage falls below a predetermined threshold.

  Accordingly, even when the anode gas is likely to be deficient after the reverse blocking switch element 22 is turned on, consumption of the anode gas in the fuel cell stack 2 is suppressed. Deterioration can be prevented. The threshold for returning the reverse blocking switch element 22 to OFF may be the same as the above-described condition for switching the reverse blocking switch element 22 to ON, or may be set to a different value.

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

  For example, in the present embodiment, the PM circuit 4 is configured by four switching elements, but is not limited thereto. For example, a PM circuit composed of five or more switching elements may be used.

  In the present embodiment, the reverse blocking IGBT is used as the reverse blocking switch element 22. However, for example, a semiconductor element in which a backflow prevention diode and an FET are connected in parallel may be used.

  In addition, the said embodiment can be combined suitably.

1 Fuel cell system 2 Fuel cell stack (fuel cell)
3 Strong battery (battery)
4 PM circuit (converter)
5 Drive motor (load)
6 Auxiliary motor (load)
7 Controller (control unit)
21 Stack breaker (contact type switch)
22 Reverse blocking type switch element (semiconductor type switch element)
61 Drive inverter (inverter)
200 Gas supply / discharge device (gas supply means)

Claims (7)

A fuel cell system that supplies anode gas and cathode gas to a fuel cell and generates electric power according to a load,
A converter that boosts at least one of the voltage on the fuel cell side and the voltage on the battery side;
A contact-type switch that switches the converter and the fuel cell from a disconnected state to a connected state when starting the fuel cell;
A semiconductor-type switching element that blocks current flowing from the converter to the fuel cell and switches the converter and the fuel cell from a disconnected state to a connected state;
Including fuel cell system. The fuel cell system according to claim 1, wherein
A fuel cell system further comprising a control unit that switches the switch element from a disconnected state to a connected state after the switch is connected when the fuel cell system is activated. The fuel cell system according to claim 1 or 2,
When starting the fuel cell system, the control unit sets the switch element to a cut-off state, then switches the switch to a connected state, and then switches the switch element to a connected state.
Fuel cell system. The fuel cell system according to any one of claims 1 to 3, wherein
When the control unit determines that the voltage of the fuel cell exceeds a predetermined threshold, the control unit sets the switch element to a connected state after switching the switch to the connected state.
Fuel cell system. In the fuel cell system according to any one of claims 1 to 4,
Gas supply means for supplying anode gas and cathode gas to the fuel cell;
An inverter connected to a voltage terminal on the fuel cell side of the converter and outputting AC power to a drive motor;
The control unit, after setting the switch element in a cut-off state, starts the fuel cell by the gas supply means, and boosts the voltage on the fuel cell side to a voltage value for protecting the inverter,
Fuel cell system. The fuel cell system according to claim 4, wherein
In the fuel cell, a plurality of battery cells are connected in series with each other,
The control unit sets the switch element to the connected state after switching the switch to the connected state based on the total voltage of the fuel cell and the variation degree of the cell voltage of each battery cell.
Fuel cell system. The fuel cell system according to any one of claims 1 to 6, wherein
When the control unit sets the switch element in the connected state and the predetermined period elapses, the total voltage of the fuel cell or the variation degree of each cell voltage is lower than a predetermined threshold value. , Returning the switch element to a shut-off state,
Fuel cell system.

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