JP2008016256A - Vehicular control device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a vehicular control device securing an idle stop time long enough even in case a capacitor is adopted as a high-voltage power storage device, and that capable of supplying enough power to an inverter for driving a motor from the capacitor at starting of the vehicle after idle stop. <P>SOLUTION: The vehicular control device is provided with a control means equipped with an idle stop mode for stopping a fuel battery, in case it is judged that a vehicle is at a stop state, a charging state of a storage battery is higher than a set value, and the capacitor is at a fully charged state. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a vehicle control device, and more particularly to a vehicle control device capable of reducing fuel consumption without degrading the running performance of a vehicle including a fuel cell and a capacitor.

In a vehicle (fuel cell vehicle) equipped with a fuel cell (fuel cell stack), in order to improve the overall efficiency of the vehicle or to complement the load response characteristics of the fuel cell, a secondary battery or a capacitor (electric Some adopt a hybrid system equipped with a power storage device such as a double layer capacitor.
Among them, capacitors are not accompanied by chemical changes like secondary batteries in charge and discharge, so they generally have a long life and high output density, and also follow the output voltage of the fuel cell well. There are many advantages such as not necessarily requiring a voltage regulator such as a large DC / DC converter. Thereby, the capacitor not only simplifies the hybrid system but also contributes to the improvement of system efficiency.

In a conventional vehicle control device including a fuel cell and a capacitor, when the remaining capacity of the capacitor drops below a predetermined value during idle stop for stopping the power generation of the fuel cell, the compressor is driven by the power of the capacitor. There is a fuel cell that is restarted, and the restarted fuel cell is caused to generate power in an operation region where the power generation efficiency is higher than the normal operation region to charge the capacitor.
JP 2004-56868 A

In a conventional vehicle control device including a fuel cell and a capacitor, when the motor driving the vehicle is in a low load state, the power supply from the capacitor to the motor is disconnected and the motor is driven only by the fuel cell. Furthermore, there is a battery that charges a capacitor with electric power from a fuel cell and charges the capacitor even before regenerative power generation by a motor occurs.
JP 2005-149920 A

In a conventional vehicle control device including a fuel cell and a secondary battery, the fuel cell is stopped in a low load region and the fuel cell is intermittently operated to supply load power from the secondary battery. In some cases, the threshold for stopping / starting the fuel cell is adjusted according to the open circuit voltage of the fuel cell in the stopped state to avoid fuel consumption for maintaining the open circuit voltage when the fuel cell is stopped.
JP 2005-71797 A

By the way, in a vehicle control device including a fuel cell and a capacitor (electric double layer capacitor) connected in parallel to a motor for driving the vehicle, an advantage that vehicle efficiency is improved by energy regeneration during vehicle deceleration. However, since the energy capacity of the capacitor is smaller than that of the secondary battery, there is a disadvantage that the idle stop for stopping the fuel cell cannot be performed or the time limit is imposed on the execution of the idle stop.
Further, when the auxiliary machine power consumption during idling stop is supplied from the capacitor, there is a problem that the state of charge (SOC) of the capacitor at the next start is lowered. At the time of acceleration after idling stop, it is necessary to supply all the electric power to the inverter that drives the motor from the capacitor until the restart of the fuel cell system is completed. However, in such a state where the state of charge of the capacitor is low, there is a problem that sufficient power supply from the capacitor to the motor cannot be secured during acceleration.
Further, in Patent Document 1, when the remaining capacity of the capacitor is reduced during the idle stop for stopping the fuel cell, an idle return means for driving the compressor by the power of the capacitor and restarting the fuel cell is restarted. There is disclosed a vehicle control device including idle charging means for generating power in a fuel cell in a higher efficiency region than in a normal operation region and charging a capacitor. However, according to this Patent Document 1, power is supplied to the auxiliary machine during idle stop from the capacitor, and when the charge state of the capacitor is lowered, the fuel cell system is restarted to supplement the capacitor. In many cases, the capacitor voltage after the stop is low, and therefore, there is a problem that sufficient power supply from the capacitor to the motor driving the vehicle cannot be secured during acceleration.

  An object of the present invention is to secure a sufficiently long idle stop time even when a capacitor is employed as a high-voltage power storage device, and to provide sufficient power for an inverter that drives a motor from the capacitor when the vehicle starts after the idle stop. An object of the present invention is to provide a vehicle control device that can be supplied.

  The present invention provides a vehicle control device including a motor for driving a vehicle, a fuel cell and a capacitor connected in parallel to the motor, the fuel cell system including the fuel cell, and the fuel cell. A fuel cell voltage detecting means for detecting a voltage between terminals of the capacitor as a fuel cell voltage, a capacitor voltage detecting means for detecting a voltage between the terminals of the capacitor as a capacitor voltage, and a fuel cell output circuit connected to the fuel cell; A fuel cell side connection means for connecting or disconnecting the power supply circuit connected to the motor, a capacitor side connection means for connecting or disconnecting a capacitor circuit for connecting the power supply circuit and the capacitor, and voltage adjustment Comprising a storage battery connected in parallel to the motor via a device, it is determined that the vehicle is in a stopped state, When it is determined that the state of charge of the storage battery is higher than a set value and the capacitor is in a fully charged state, control means having an idle stop mode for stopping the fuel cell system is provided. Features.

  In the vehicle control device according to the present invention, the idle stop mode for stopping the fuel cell system is not performed unless the capacitor is fully charged. Therefore, the amount of electric power stored in the capacitor is insufficient during acceleration traveling immediately after the idle stop mode. Acceleration failure will not occur. Thereby, this vehicle control device can realize a reduction in fuel consumption of the fuel cell without degrading the running performance of the vehicle.

The vehicle control device according to the present invention performs the idle stop mode and stops the fuel cell system when the vehicle is in a stopped state, the storage battery is charged higher than a set value, and the capacitor is fully charged. By doing so, it is possible to avoid a shortage of the amount of electric power stored in the capacitor during acceleration traveling immediately after the idle stop mode, and to reduce the fuel consumption of the fuel cell without degrading the traveling performance of the vehicle. .
Hereinafter, embodiments of the present invention will be described in detail and specifically based on the drawings.

1 to 3 show an embodiment of the present invention. 1 is a system configuration diagram of the vehicle control device, FIG. 2 is a transition diagram of a control state of the vehicle control device, and FIG. 3 is a flowchart of control of the vehicle control device.
In FIG. 1, reference numeral 1 denotes a vehicle control device for a vehicle (fuel cell vehicle). The vehicle control device 1 includes a motor 2 that drives the vehicle, and includes a fuel cell (fuel cell stack: FC) 3 and a capacitor 4 (power storage device) connected in parallel to the motor 2. . The fuel cell 3 and the capacitor 4 are connected to the motor 2 via the inverter 5.
The vehicle control device 1 includes a vehicle system 6 including a motor 2 and an inverter 5 that supplies electric power to the motor 2, a fuel cell 3, an air compressor that supplies compressed air (oxidant) to the fuel cell 3, and the like. And a fuel cell system (FC system) 7 including a capacitor 4.
The motor 2 and the inverter 5 are connected by a three-phase electric wire 8. The fuel cell 3 and the inverter 5 are connected by first and second main electric wires 9 and 10 in parallel. The first and second main electric wires 9 and 10 are connected to one end side of the first and second sub electric wires 11 and 12 in parallel, and the other end side of the first and second sub electric wires 11 and 12 is connected to the first and second main electric wires 9 and 10, respectively. The capacitor 4 is connected. Thereby, the fuel cell 3 and the capacitor 4 are connected in parallel to the motor 2.
The fuel cell 3 generates power by receiving supply of fuel (hydrogen gas) and oxidant (air). The inverter 5 converts the DC power generated by the fuel cell 3 into three-phase AC power, and supplies the converted three-phase AC power to the motor 2. The motor 2 is driven by the three-phase AC power supplied from the inverter 5 and drives the drive wheels via the transmission. The inverter 5 performs regenerative control that converts the negative torque of the motor 2 into electric power when the vehicle is decelerated, in addition to the drive control of the motor 2.
The capacitor 4 is connected to the motor 2 in parallel with the fuel cell 3 to assist the power supply to the inverter 5 and to accept the power generated by the fuel cell 3 and the regenerative power from the inverter 5 during vehicle deceleration. . The fuel cell system 7 does not include a device such as a DC / DC converter (voltage adjustment device) that adjusts the voltage and current between the fuel cell 3 and the capacitor 4.
Supply of power from the capacitor 4 to the inverter 5 or supply of power from the fuel cell 3 or the inverter 5 to the capacitor 4 depends on the voltage relationship between the capacitor 4 and the first and second main electric wires 9 and 10 of the high voltage bus. Determined. In addition, as the capacitor 4, a power that dynamically follows the fluctuation of the fuel cell voltage due to the load fluctuation, such as a large-capacity electric double layer capacitor or a capacitor using a metal complex polymer as an electrode material. It is possible to use (energy) storage devices.

The first and second main electric wires 9 and 10 closer to the fuel cell 3 than the connecting portions of the first and second sub electric wires 11 and 12 are provided with fuel cell relays 13 serving as fuel cell side connection means. . The first and second main electric wires 9 and 10 between the fuel cell relay 13 and the fuel cell 3 are fuel cells which are fuel cell voltage detecting means for detecting the voltage across the terminals of the fuel cell 3 as the fuel cell voltage. A voltmeter 14 is connected. A backflow prevention diode 15 is provided on the first main electric wire 9 between the fuel cell 3 and the fuel cell voltmeter 14. The backflow prevention diode 15 prevents backflow of current from the inverter 5 side to the fuel cell 3 side.
The first and second sub-wires 11 and 12 are provided with capacitor relays 16 serving as capacitor-side connection means between the first and second main wires 9 and 10 and the capacitor 4. The first and second sub wires 11 and 12 between the capacitor relay 16 and the capacitor 4 are provided with a capacitor voltmeter 17 which is a capacitor voltage detecting means for detecting a voltage between terminals of the capacitor 4 as a capacitor voltage. Yes.
The first and second sub electric wires 11 and 12 are connected to the third and fourth sub electric wires 18 and 19 arranged in parallel to bypass the capacitor relay 16. A precharge circuit 20 is provided on the third and fourth sub wires 18 and 19. The precharge circuit 20 can charge the capacitor 4 and charges the capacitor 4 while limiting the charging current. The precharge circuit 20 generally includes a semiconductor element for limiting current and a limiting resistor, or is configured from components such as a semiconductor element capable of switching control.
This precharge circuit 20 is provided with a capacitor in order to prevent an overcurrent that may occur when the capacitor relay 16 is connected when the value of the capacitor voltage on the capacitor 4 side is lower than the value of the voltage on the inverter 5 side. Prior to connection of the relay 16, the capacitor 4 is charged while limiting the current.
The fuel cell relay 13 opens and closes, thereby allowing a fuel cell output circuit (fuel cell bus) 21 connected to the fuel cell 3 and a power supply circuit (high voltage) connected to the motor 2 via the inverter 5. Bus) 22 is connected or disconnected. The capacitor relay 16 opens or closes to connect or disconnect the power supply circuit 22 connected to the motor 2 and the capacitor circuit (capacitor bus) 23 connected to the capacitor 4.
Accordingly, the first and second main electric wires 9 and 10 and the first and second sub electric wires 11 and 12 are connected to the fuel cell output circuit 21 and the power supply circuit by the fuel cell relay 13 and the capacitor relay 16. 22 and capacitor circuit 23. The bus voltages of these three circuits 21 to 23 match when the fuel cell relay 13 and the capacitor relay 16 are connected together, but the fuel cell relay 13 and the capacitor relay 16 are opened. There may be differences in the conditions. The inverter 5 is provided with a smoothing capacitor at the input stage for suppressing fluctuations in the input voltage of the power supply circuit 22.

One end sides of fifth and sixth sub wires 24 and 25 are connected to the first and second main wires 9 and 10, respectively. The other ends of the fifth and sixth sub-wires 24 and 25 are connected to a high-voltage auxiliary device 26 of a high-voltage system. The high-voltage auxiliary machines 26 include various auxiliary machines driven at a high voltage such as an air compressor for supplying compressed air to the fuel cell 3 and an air-conditioning compressor of a vehicle air conditioner. The various auxiliary machines of the high-voltage auxiliary machines 26 are connected to the other ends of the fifth and sixth sub-wires 24 and 25 through inverters, respectively, and the input voltage from the power supply circuit 22 is connected to the input stage inside the inverter. A smoothing capacitor is provided to suppress fluctuations in the above.
The first and second main electric wires 9 and 10 are connected to one end sides of the seventh and eighth sub electric wires 27 and 28, respectively. The other end side of the seventh and eighth sub electric wires 27 and 28 is connected to an auxiliary machine driving battery 30 as a storage battery via a bidirectional DC / DC converter 29 which is a voltage adjusting device. The seventh and eighth sub electric wires 27 and 28 between the bidirectional DC / DC converter 29 and the auxiliary drive battery 30 are connected to one end side of the ninth and tenth sub electric wires 31 and 32 in parallel, respectively. The other end side of the ninth and tenth sub electric wires 31 and 32 is connected to the vehicle auxiliary equipment 33 of the low voltage system.
The bidirectional DC / DC converter 29 is connected to the inverter 5 in parallel with the capacitor 4, and the electric power from the fuel cell 3 and the capacitor 4 or the voltage of the regenerative power from the inverter 5 is supplied to the vehicle auxiliary equipment 33. The voltage for driving (usually 12V system) is converted, and conversely, the voltage of the battery 30 for driving the auxiliary machine is converted into the voltage for driving the high voltage auxiliary machine 26, or the capacitor 4 is Convert to voltage for auxiliary charge. The voltage adjustment device is not limited to the bidirectional DC / DC converter 29, and is a DC / DC converter including both a step-up DC / DC converter and a step-down DC / DC converter in parallel. It is also possible.
The auxiliary drive battery 30 is connected to the low voltage side of the bidirectional DC / DC converter 29 and connected to the motor 2 in parallel with the fuel cell 3 and the capacitor 4. The auxiliary drive battery 30 includes a charge state sensor 34 that is a charge state detection unit for measuring a state of charge (SOC), and includes a high voltage auxiliary device 26 and a vehicle auxiliary device 33. To drive.
The vehicle auxiliary machinery 33 is composed of various auxiliary devices for a low voltage system vehicle such as a vehicle headlamp, a radio, a water pump, etc., and the auxiliary drive battery 30 for the bidirectional DC / DC converter 29. Connected in parallel.

The inverter 5, the fuel cell relay 13, the fuel cell voltmeter 14, the capacitor relay 16, the capacitor voltmeter 17, the precharge circuit 20, the high voltage auxiliary machinery 26, the bidirectional DC / DC converter 29, and the vehicle The auxiliary machinery 33 and the charge state sensor 34 are connected to the control means 35.
The control means 35 includes a key switch 36 that is turned on / off by an operation of an engine key, a vehicle speed sensor 37 that detects a vehicle speed for determining a vehicle stop state, and an on / off operation of a brake pedal. A brake switch 38 and a shift position switch 39 for detecting a shift position (range) of the transmission are connected, and a memory 40 for storing various information collected by the switches / sensors 36 to 39 is provided therein.
The control means 35 controls the vehicle system 6 by driving each control object such as the vehicle auxiliary machine 33 based on various information collected by the switches / sensors 36 to 39 and information stored in the internal memory 40. At the same time, each control object such as an air compressor that pumps air to the fuel cell 3 is driven to control the fuel cell system 7.

As described above, the vehicle control device 1 that includes the motor 2 that drives the vehicle and includes the fuel cell 3 and the capacitor 4 that are connected in parallel to the motor 2 includes the fuel cell system 7 that includes the fuel cell 3. A fuel cell voltmeter 14 that detects the voltage between the terminals of the fuel cell 3 as a fuel cell voltage, and a capacitor voltmeter 17 that detects the voltage between the terminals of the capacitor 4 as a capacitor voltage. A fuel cell relay 13 for connecting or blocking the connected fuel cell output circuit 21 and the power supply circuit 22 connected to the motor 2 is provided, and a capacitor circuit 23 for connecting the power supply circuit 22 and the capacitor 4 is connected or A capacitor relay 16 that cuts off and an auxiliary drive battery 30 that is connected in parallel to the motor 2 via a DC / DC converter 29 are provided. That.
The control unit 35 of the vehicle control device 1 includes a mode setting unit 41 for setting various modes (M1 to M5) shown in FIG. 2 and a mode switching for selectively switching the various modes set in the mode setting unit 41. A unit 42 and a vehicle stop determination unit 43 that determines whether or not the vehicle is stopped are provided.
The control means 35 includes, in the mode setting unit 41, the normal operation mode (M1), the vehicle stop mode (M2), the capacitor auxiliary charge mode (M3), the idle stop mode (M4), and the restart mode (M5). And. The control means 35 controls to switch the various modes (M1 to M5) to a predetermined mode in the mode switching unit 42 under a predetermined condition.
When it is determined that the capacitor 4 is not in the fully charged state in the capacitor supplement charging mode (M3), the control unit 35 supplementarily charges the capacitor 4 with the auxiliary device driving battery 30. The controller 35 sets the output voltage of the DC / DC converter 29 to a value equal to the maximum voltage of the capacitor 4 when the capacitor 4 is supplementarily charged.
In the idle stop mode (M4), the control means 35 determines that the vehicle is in a stopped state, the state of charge (SOC) of the accessory driving battery 30 is higher than a set value (threshold), and the capacitor 4 is full. When it is determined that the battery is in the charged state, the fuel cell system 7 is stopped.
In the restart mode (M5), the control means 35 determines that the vehicle is not in a stop state during execution of the idle stop mode (M4), or the charge state (SOC) of the auxiliary device drive battery 30 is If it is determined that the fuel cell system 7 is below the set value, the fuel cell system 7 is restarted. The control means 35 supplies power from the capacitor 4 when there is an output request from the motor 2 in the restart mode (M5). In the restart mode, the control means 35 restarts the fuel cell system 7 using the electric power of the auxiliary drive battery 30.

Next, the control of the vehicle control device 1 will be described with reference to the transition diagram of the control state shown in FIG.
As shown in FIG. 2, in the normal operation mode (M1), the fuel cell 3 and the capacitor 4 are both connected to the power supply circuit 22, and the fuel cell 3 and the capacitor 4 supply power to the load. Regenerative energy during deceleration is stored in the capacitor 4.
In the normal operation mode (M1) or the restart mode (M5) of the fuel cell system 7, the vehicle stop determination unit 43 determines that the vehicle is stopped, and the charge state of the auxiliary battery 30 is a set value (threshold value). ), The vehicle shifts to the vehicle stop mode (M2).
Here, the case where the state of charge of the auxiliary machine driving battery 30 is sufficiently high means that energy sufficient to supply power in the auxiliary charging of the capacitor 4 or in the idle stop mode (M4) is stored. The condition that the state of charge of the auxiliary device driving battery 30 is sufficiently high is determined according to the state of charge of the capacitor 4, the load in the idle stop mode (M4), the time of the assumed idle stop mode, and the like.
For example, when the vehicle speed is zero (0) by the vehicle speed sensor 37 and the brake switch 38 is on, or the shift position of the transmission by the shift position switch 39 is “N” or “P”, the vehicle is stopped. This is determined by continuing the above.
In the normal operation mode (M1), since the fuel cell 3 and the capacitor 4 are connected to the power supply circuit 22, the capacitor voltage is always equal to or higher than the fuel cell voltage. Further, when the vehicle decelerates, the energy regenerated by the inverter 5 is stored in the capacitor 4, so that the capacitor voltage in the vehicle stop mode (M 2) is not less than the idle voltage of the fuel cell 3 and not more than the maximum voltage of the capacitor 4. Become.
In the vehicle stop mode (M2), when it is determined by the capacitor voltage that the capacitor 4 is not fully charged, the mode is shifted to the capacitor auxiliary charge mode (M3). In the capacitor auxiliary charging mode (M3), the electric power of the auxiliary machine driving battery 30 is supplied to the capacitor 4 via the bidirectional DC / DC converter 29, and the auxiliary charging is performed until the capacitor 4 is fully charged. Even if the capacitor voltage rises due to supplementary charging, the capacitor 4 is directly applied to the output terminal of the fuel cell 3 by the backflow prevention diode 14 provided in the output stage of the fuel cell 3. Therefore, the fuel cell 3 is not adversely affected.
In the capacitor auxiliary charging mode (M3), when the driver requests to start, that is, the brake switch 38 is turned off, or the shift position switch 39 shifts the shift position to “D” or “R”. If detected, or if the charge state of the auxiliary drive battery 30 falls below a set value (threshold), the auxiliary charge from the auxiliary drive battery 30 to the capacitor 4 is stopped, and the normal operation mode (M1) is stopped. Return to).
When it is determined that the capacitor 4 is fully charged in the vehicle stop mode (M2), and when the capacitor 4 is fully charged in the capacitor auxiliary charge mode (M3), the fuel cell output circuit 21 is powered. By opening the fuel cell relay 13 for connection to the supply circuit 22, the fuel cell 3 is separated from the power supply circuit 22, and shifts to an idle stop mode (M 4) in which the fuel cell system 7 is stopped.
In the idle stop mode (M4), all the auxiliary devices of the fuel cell system 7 such as an air compressor for supplying compressed air to the fuel cell 3 are stopped, and only the auxiliary devices of the vehicle system 6 are required as necessary. It is driven by the electric power of the auxiliary drive battery 30. That is, in the idle stop mode (M4), electric power is directly supplied from the accessory driving battery 30 to the low-voltage vehicle auxiliary equipment 33 such as a radio and a headlight, and a high-voltage system such as an air conditioning compressor is supplied. When there is a request for driving the high-voltage auxiliary machinery 26, the boosted power is supplied from the auxiliary device driving battery 30 via the bidirectional DC / DC converter 29.
At this time, in order to prevent the power supply from the capacitor 4 to the high voltage auxiliary machinery 26 in the idle stop mode (M4), that is, in order to maintain the capacitor 4 in a fully charged state, the auxiliary device driving battery 30 And the booster side output voltage of the bidirectional DC / DC converter 29 provided between the capacitor 4 and the capacitor 4 is set to the maximum voltage of the capacitor 4.
In the idle stop mode (M4), when the brake switch 38 is turned off or the shift position switch 39 detects the shift position to “D” or “R”, or the auxiliary drive battery 30 is charged. When the state falls below the set value, the fuel cell system 7 shifts to the restart mode (M5).
In the restart mode (M5) of the fuel cell system 7, the boosted electric power is supplied from the auxiliary device driving battery 30 to the air compressor or the like that is an auxiliary device of the fuel cell system 7 via the bidirectional DC / DC converter 29. When the drive of the motor 2 is requested at the same time as supplying and starting the fuel cell system 7, power is supplied from the capacitor 4 to the inverter 5 even before the restart of the fuel cell system 7 is completed. To do.
In the restart mode (M5) of the fuel cell system 7, when the start of the fuel cell system 7 is completed, the fuel cell relay 13 is connected, the fuel cell output circuit 21 is connected to the power supply circuit 22, and the normal operation mode ( M1) to move to (f).

Next, the control of the vehicle control device 1 will be described along the flowchart of FIG.
As shown in FIG. 3, the vehicle control apparatus 1 determines whether or not the vehicle is stopped and the charge state of the accessory driving battery 30 is higher than a set value in the normal operation mode (M1) (S01). Is determined (S02). In this determination (S02), when the vehicle is not stopped, and when the state of charge of the auxiliary machine driving battery 30 is lower than the set value even when the vehicle is stopped, and NO is determined, The operation mode (M1) remains, and this determination (S02) is continued.
In the determination (S02), when the vehicle is stopped and the state of charge of the auxiliary battery 30 is higher than the set value and it is determined YES, the vehicle shifts to the vehicle stop mode (M2) and the capacitor voltage ( Vcap) is measured (S03). Based on the measured capacitor voltage (Vcap), it is determined whether or not the charged state of the capacitor 4 is a fully charged state (S04).
In this determination (S04), when the capacitor 4 is in a fully charged state and it is determined YES, the idle stop is started (S10), and the process proceeds to the idle stop mode (M4). If it is determined in this determination (S04) that the capacitor 4 is not in a fully charged state but is NO, the capacitor compensation that supplementarily charges the capacitor 4 from the auxiliary device driving battery 30 via the bidirectional DC / DC converter 29 is performed. A transition is made to the charging mode (M3) (S05).
In the capacitor auxiliary charging mode (M3), as the confirmation of the driver's intention to start and the charging state of the auxiliary device driving battery 30, the vehicle is in a stopped state and the charging state of the auxiliary device driving battery 30 is lower than the set value. It is determined whether or not it is high (S06).
In this determination (S06), when the driver's start request is recognized, that is, it is detected that the brake switch 38 is turned off or the shift position is shifted to "D" or "R" by the shift position switch 39. If it is determined that the vehicle is not in a stopped state, or if the state of charge of the auxiliary device driving battery 30 is lower than the set value and it is determined NO, the normality of the determination (S02) Return to the operation mode (M1).
In this determination (S06), when it is determined that the vehicle is still stopped and the state of charge of the auxiliary battery 30 is higher than the set value, the capacitor voltage (Vcap) is measured again (S07). Based on the measured capacitor voltage (Vcap), it is determined whether or not the charged state of the capacitor 4 is a fully charged state (S08).
In this determination (S08), if the capacitor 4 is not yet fully charged and the determination is NO, the process returns to the determination (S06). In this determination (S08), if the capacitor 4 is fully charged and if YES, the auxiliary charging of the capacitor 4 is terminated (S09).
When the capacitor 4 is fully charged and the auxiliary charging from the auxiliary machine driving battery 30 is completed (S09), the idle stop is started (S10), and the process proceeds to the idle stop mode (M4).
In the idle stop mode (M4), it is determined whether or not the vehicle is in a stopped state and the state of charge of the accessory driving battery 30 is higher than a set value (S11).
In this determination (S11), when the vehicle is in a stopped state and the charging state of the auxiliary machine driving battery 30 is higher than the set value, if YES, the idle stop mode (M4) is executed, and this determination (S11) Continue.
In this determination (S11), when the stop state of the vehicle is released, that is, when the brake switch 38 is turned off or the shift position switch 39 detects that the shift position has shifted to "D" or "R", or If the state of charge of the auxiliary drive battery 30 is lower than the set value and the determination is NO, the fuel cell system 7 is restarted, and the process proceeds to the restart mode (M5) of the fuel cell system 7 (S12).
When the restart is completed in the restart mode (M5) (S12), the process returns to the determination (S02) and shifts to the normal operation mode (M1).

Next, a method for calculating the set value (threshold value) of the state of charge (SOC) of the auxiliary machine driving battery 30 as a condition for shifting from the normal operation mode (M1) to the vehicle stop mode (M2) will be described. .
The energy (electric power) that the auxiliary drive battery 30 must supply during the period from the vehicle stop mode (M2) to the restart mode (M5) of the fuel cell system 7 is:
(1) Capacitor auxiliary charging energy in the capacitor auxiliary charging mode (M3);
(2) Auxiliary drive energy of the vehicle system 6 in the idle stop mode (M4),
(3) Auxiliary drive energy of the fuel cell system 7 in the restart mode (M5) of the fuel cell system 7,
Is the sum of
Therefore, the charging state of the auxiliary machine driving battery 30 in the normal operation mode (M1) is (1) capacitor auxiliary charging energy, (2) auxiliary machine driving energy of the vehicle system 6, and (3) fuel cell system 7 If the sum is not more than the sum of the auxiliary drive energy, there arises a problem that the fuel cell system 7 cannot be restarted.
(1) Capacitor auxiliary charging energy, (2) auxiliary machine driving energy of vehicle system 6, and (3) auxiliary machine driving energy of fuel cell system 7 are calculated as follows.
The (1) capacitor auxiliary charging energy is calculated from the capacitor voltage in the vehicle stop mode (M2) as energy required for auxiliary charging to a fully charged state (variable depending on the capacitor voltage).
(2) The auxiliary drive energy of the vehicle system 6 is calculated from the product of the average or maximum power consumption in the idle stop mode (M4) and the desired idle stop time (as a constant, in the memory 40 of the control means 35). Stored).
(3) The auxiliary drive energy of the fuel cell system 7 is calculated as energy required to drive the auxiliary device of the fuel cell system 7 in the restart mode (M5) of the fuel cell system 7 (as a constant, control Stored in the memory 40 of the means 35).
Therefore, the set value of the state of charge of the auxiliary device driving battery 30 when shifting from the normal operation mode (M1) to the vehicle stop mode (M2) is stored as a constant in the memory 40 of the control means 35 (2 It is necessary to make it larger than the sum of the auxiliary driving energy of the vehicle system 6 and the auxiliary driving energy of the (3) fuel cell system 7 and the (1) capacitor auxiliary charging energy calculated from the capacitor voltage. That is, the set value of the state of charge (SOC) of the auxiliary device driving battery 30 can be determined as a function of the capacitor voltage.
As described above, the vehicle control device 1 controls the vehicle system 6 and the fuel cell system 7 to ensure a sufficiently long idle stop time and to fully charge the capacitor 4 prior to the idle stop. Thus, sufficient electric power can be supplied from the capacitor 4 to the motor 4 at the next vehicle start.

Thus, vehicle control apparatus 1 determines that the vehicle is in a stopped state, determines that the charging state of auxiliary machine driving battery 30 is higher than the set value, and capacitor 4 is fully charged. In some cases, an idle stop mode (M4) for stopping the fuel cell system 7 is provided.
Therefore, the vehicle control apparatus 1 does not execute the idle stop mode (M1) for stopping the fuel cell system 7 unless the capacitor 4 is in a fully charged state. Therefore, during acceleration running immediately after the idle stop mode (M1), Acceleration failure due to a shortage of the amount of power stored in the capacitor 4 does not occur. Thereby, this vehicle control device 1 can realize a reduction in the amount of fuel (hydrogen) consumed by the fuel cell 3 without degrading the running performance of the vehicle.
The control means 35 has a capacitor supplement charging mode in which the capacitor 4 is supplemented by the auxiliary device driving battery 30 when it is determined that the capacitor 4 is not fully charged.
The control means 35 sets the output voltage of the DC / DC converter 29 to a value equal to the maximum voltage of the capacitor 4 when the capacitor 4 is supplementarily charged. Therefore, the vehicle control device 1 is not supplied with power from the capacitor 4 even when the high-voltage auxiliary machinery 26 such as an air-conditioning compressor is operating when the vehicle is stopped. Thereby, this vehicle control apparatus 1 can maintain the amount of electric power stored in the capacitor 4.
Further, the vehicle control device 1 determines that the vehicle is in a stopped state, determines that the charging state of the accessory driving battery 30 is higher than a set value, and the capacitor 4 is fully charged. In the idle stop mode (M4) for stopping the fuel cell system 7 and the idle stop mode (M4), when it is determined that the vehicle is not in the stopped state, or the charge state of the auxiliary drive battery 30 is When it is determined that the fuel cell system 7 is below the set value, a restart mode (M5) for restarting the fuel cell system 7 is provided.
Therefore, the vehicle control device 1 operates the vehicle after starting or restarts the fuel cell system 7 when the amount of power stored in the auxiliary drive battery 30 decreases. It is possible to respond immediately to a person's start request. Thereby, this vehicle control device 1 can realize a reduction in the amount of fuel (hydrogen) consumed by the fuel cell 3 without degrading the starting performance.
The control means 35 supplies electric power from the capacitor 4 when there is an output request from the motor 2 in the restart mode (M3). Thereby, this vehicle control device 1 can immediately respond to the driver's start acceleration request after the idle stop is performed.
In the restart mode (M3), the control means 35 restarts the fuel cell system 7 using the electric power of the auxiliary drive battery 30. Thus, the vehicle control device 1 can restart the fuel cell system 7 without using the electric power stored in the capacitor 4.
In the above embodiment, one of the conditions for shifting to the idle stop mode has been described on the assumption that the capacitor is fully charged. However, in the restart mode, all drive energy must be supplied from the capacitor. Even if it is necessary, if the capacity of the capacitor is superior, it is possible to implement the idle stop mode by changing the condition to “capacitor SOC is more than a set threshold value” instead of full capacitor charge. is there.

  The vehicle control device of the present invention avoids a shortage of the amount of electric power stored in the capacitor during acceleration traveling immediately after the idle stop mode for stopping the fuel cell system, and without degrading the traveling performance of the vehicle. The fuel consumption is reduced, and the present invention can be applied to the control of other devices other than the control of a vehicle equipped with a fuel cell.

It is a system block diagram of the control apparatus for vehicles. It is a transition diagram of the control state of the control device for vehicles. It is a flowchart of control of the control apparatus for vehicles.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Vehicle control apparatus 2 Motor 3 Fuel cell 4 Capacitor 5 Inverter 6 Vehicle system 7 Fuel cell system 13 Fuel cell relay 14 Fuel cell voltmeter 15 Backflow prevention diode 16 Capacitor relay 17 Capacitor voltmeter 20 Precharge circuit 21 Fuel Cell Output Circuit 22 Power Supply Circuit 23 Capacitor Circuit 26 High Voltage Auxiliary Equipment 29 Bidirectional DC / DC Converter 30 Auxiliary Drive Battery 33 Vehicle Auxiliary Equipment 34 Charging State Sensor 35 Control Unit 37 Vehicle Speed Sensor 38 Brake Switch 39 Shift position switch 40 Memory 41 Mode setting unit 42 Mode switching unit 43 Vehicle stop determination unit

Claims (6)

  A vehicle control device comprising a motor for driving a vehicle and comprising a fuel cell and a capacitor connected in parallel to the motor, comprising a fuel cell system including the fuel cell, and a terminal voltage of the fuel cell A fuel cell voltage detecting means for detecting the voltage between the terminals of the capacitor as a capacitor voltage, and a fuel cell output circuit connected to the fuel cell and connected to the motor. A fuel cell side connection means for connecting or disconnecting the power supply circuit, and a capacitor side connection means for connecting or disconnecting a capacitor circuit for connecting the power supply circuit and the capacitor. A storage battery connected in parallel to the motor, the vehicle is determined to be stopped, and the storage battery When it is determined that the power state is higher than a set value and the capacitor is in a fully charged state, control means having an idle stop mode for stopping the fuel cell system is provided. Vehicle control device.   2. The vehicle according to claim 1, wherein the control unit includes a capacitor supplement charge mode in which the capacitor is supplemented by the storage battery when it is determined that the capacitor is not fully charged. 3. Control device.   3. The vehicle control device according to claim 2, wherein when the capacitor is supplementarily charged, the output voltage of the voltage adjusting unit is set to a value equal to the maximum voltage of the capacitor.   A vehicle control device comprising a motor for driving a vehicle and comprising a fuel cell and a capacitor connected in parallel to the motor, comprising a fuel cell system including the fuel cell, and a terminal voltage of the fuel cell A fuel cell voltage detecting means for detecting the voltage between the terminals of the capacitor as a capacitor voltage, and a fuel cell output circuit connected to the fuel cell and connected to the motor. A fuel cell side connection means for connecting or disconnecting the power supply circuit, and a capacitor side connection means for connecting or disconnecting a capacitor circuit for connecting the power supply circuit and the capacitor. A storage battery connected in parallel to the motor, the vehicle is determined to be stopped, and the storage battery When it is determined that the power state is higher than a set value and the capacitor is fully charged, the vehicle is stopped during the idle stop mode in which the fuel cell system is stopped and the idle stop mode is being executed. When it is determined that the storage battery is not in a state, or when it is determined that the state of charge of the storage battery is equal to or less than a set value, a control means including a restart mode for restarting the fuel cell system A control apparatus for a vehicle.   5. The vehicle control device according to claim 4, wherein the control unit supplies electric power from the capacitor when there is an output request from the motor in the restart mode.   5. The vehicle control device according to claim 4, wherein the control unit restarts the fuel cell system using electric power of the storage battery in the restart mode.

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