JP2004175313A - Vehicle controller - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a technology to carry out an appropriate fail processing when an abnormality has occurred in a vehicle with wheels driven by using power of a dynamo-electric motor. <P>SOLUTION: The vehicle, in which the dynamo-electric motor, a power transmission mechanism, and a controller are provided to each of at least two driving wheels is characterized in that, when an abnormality has occurred on the controller of one driving wheel, the controller of the other driving wheel controls the power transmission mechanism of the former driving wheel to make the driving torque of the former driving wheel controllable, and thus, the driving torque of both driving wheels is matched with each other. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a vehicle such as an automobile, and more particularly to a vehicle control technique that drives wheels using the power of an electric motor.
[0002]
[Prior art]
2. Description of the Related Art In recent years, a four-wheel drive vehicle in which one of a front wheel and a rear wheel of a vehicle is driven by an internal combustion engine and / or a motor and the other is driven by a motor as an automobile that drives wheels using the power of an electric motor (motor). Has been proposed (for example, see Patent Document 1).
[Patent Document 1]
JP-A-11-208304
[Problems to be solved by the invention]
By the way, in the above-described conventional technology, no consideration is given to a case where an abnormality occurs in a drive system including a motor or a control system of the motor.
[0003]
The present invention has been made in view of the above-described circumstances, and provides a technology capable of performing a suitable fail process when an abnormality occurs in a vehicle that drives wheels using the power of an electric motor. Aim.
[0004]
[Means for Solving the Problems]
The present invention employs the following means in order to solve the above problems. That is, the vehicle control device according to the present invention includes:
A plurality of wheels provided on the vehicle;
An electric motor provided on each of at least two drive wheels of the wheels,
A power transmission mechanism that changes a power transmission rate between the electric motor and the drive wheels;
A control device that is provided for each drive wheel and controls an electric motor and a power transmission mechanism of each drive wheel;
A failure processing unit that controls a power transmission mechanism of the one drive wheel by a control device of another drive wheel when an abnormality occurs in the control device of one of the drive wheels;
Was provided.
[0005]
In a vehicle in which an electric motor, a power transmission mechanism, and a control device are provided for at least two drive wheels, when an abnormality occurs in a control device for one drive wheel, the vehicle control device controls the other drive wheels. The most characteristic feature is that the control device controls the power transmission mechanism of one drive wheel to control the drive torque of one drive wheel.
[0006]
In such a vehicle control device, when an abnormality occurs in the control device for one drive wheel, the fail processing means activates the control device for the other drive wheel so as to control the power transmission mechanism of the one drive wheel.
[0007]
In this case, the control device of the other drive wheel controls the power transmission mechanism of one drive wheel in addition to the electric motor and the power transmission mechanism of the other drive wheel.
[0008]
As a result, the power transmission rate of the power transmission mechanism of one drive wheel is controlled, so that the drive torque transmitted from the electric motor to the drive wheel in one drive wheel becomes appropriate.
[0009]
In the present invention, when the driving wheels are the left and right front wheels of the vehicle, or when the driving wheels are the left and right rear wheels of the vehicle, the failure processing means determines that the control device for one of the driving wheels has failed, and May control the power transmission mechanism of one of the drive wheels.
[0010]
In this case, the control device for the other drive wheel controls the electric motor and the power transmission mechanism of the other drive wheel, and also controls the power transmission mechanism of the one drive wheel.
[0011]
As a result, the driving torque transmitted from the electric motor to the driving wheels in one of the driving wheels has an appropriate magnitude, so that the driving torque of the one driving wheel and the driving torque of the other driving wheel are harmonized. A decrease in running stability of the vehicle is suppressed.
[0012]
Further, in the case where the drive wheels according to the present invention are four wheels arranged in front, rear, left and right of the vehicle, the fail processing means, when the control device of one drive wheel generates an abnormality, the one drive wheel and The power transmission mechanism of the one drive wheel may be controlled by a control device for the other drive wheel at the opposite corner.
[0013]
For example, (1) when the control device for the left front wheel of the vehicle is abnormal, the control device for the right rear wheel controls the electric motor and the power transmission mechanism for the right rear wheel and controls the power transmission mechanism for the left front wheel; (2) When the control device for the right front wheel of the vehicle is abnormal, the control device for the left rear wheel controls the electric motor and the power transmission mechanism for the left rear wheel and the power transmission mechanism for the right front wheel, and (3) (4) When the control device for the right rear wheel of the vehicle is abnormal, the control device for the left front wheel controls the electric motor and the power transmission mechanism for the left rear wheel, and also controls the power transmission mechanism for the right rear wheel. When the control device for the left rear wheel of the vehicle is abnormal, the control device for the right front wheel controls the electric motor and the power transmission mechanism for the right front wheel and controls the control device for the left rear wheel.
[0014]
When the power transmission mechanism of the drive wheel in which the abnormality has occurred is controlled by the control device for the drive wheel opposite to the drive wheel, the drive torque of the front and rear wheels is harmonized and the drive torque of the left and right wheels is simultaneously adjusted. Harmony is achieved, whereby a decrease in the running stability of the vehicle is suppressed.
[0015]
Here, as a mode in which an abnormality occurs in the control device, a mode in which the control device falls into an abnormal state in a state where the electric motor is operated, and a mode in which the control device falls into an abnormal state in a state in which the operation of the motor is stopped are assumed. You.
[0016]
First, when the control device for one of the plurality of drive wheels falls into an abnormal state while the electric motor is operating, the control device for the other drive wheel transmits the power transmitted from the power transmission mechanism of the one drive wheel. By controlling the ratio, the drive torque of one drive wheel can be set to a desired value.
[0017]
For example, when the torque of the motor of one drive wheel is higher than the torque of the motor of the other drive wheel, the control device of the other drive wheel reduces the power transmission rate of the power transmission mechanism of one drive wheel by reducing The drive torque of one drive wheel is reduced to the same level as the drive torque of the other drive wheels.
[0018]
When the torque of the electric motor of one drive wheel is lower than the torque of the electric motor of the other drive wheel, the control device of the other drive wheel cuts off the power transmission by the power transmission mechanism of the one drive wheel. Is also good. Note that the control device for the other drive wheels reduces the torque of the electric motor of the other drive wheels or the transmission rate of the power transmission mechanism of the other drive wheels to reduce the drive torque of the other drive wheels. The driving torque may be reduced to the same level as the driving torque of one driving wheel.
[0019]
Next, when the control device for one of the plurality of drive wheels becomes abnormal while the operation of the electric motor is stopped, the control device for the other drive wheel sets the power transmission mechanism for the one drive wheel. , The drive torque of one drive wheel may be set to “0” by interrupting the power transmission by the drive.
[0020]
At this time, if the one drive wheel and the other drive wheel are drive wheels arranged on the left and right sides of the vehicle, the control device for the other drive wheel shuts off the power transmission by the power transmission mechanism of the one drive wheel. At the same time, it is preferable to shut off the power transmission by the power transmission mechanism of the other drive wheels.
[0021]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, specific embodiments of a vehicle control device according to the present invention will be described with reference to the drawings.
[0022]
FIG. 1 is a diagram showing a schematic configuration of a vehicle to which the present invention is applied. The vehicle 1 shown in FIG. 1 is a hybrid four-wheel drive vehicle driven by an internal combustion engine and a motor.
[0023]
The vehicle 1 has an internal combustion engine 2 mounted thereon. A transmission 3 that changes the rotation speed of an engine output shaft (crankshaft) is connected to the internal combustion engine 2. The axle 5 of the right front wheel 4 and the axle 7 of the left front wheel 6 are connected to the transmission 3.
[0024]
In this case, the rotational torque of the engine output shaft of the internal combustion engine 2 is distributed to the left and right front wheels 4 and 6 via the transmission 3 and the axles 5 and 7.
[0025]
Next, the axle 9 of the right rear wheel 8 of the vehicle 1 is connected to the motor shaft 12 of the first motor (M1) 11 via the first clutch 10. The first motor (M1) 11 corresponds to the electric motor according to the present invention, and is a three-phase AC motor or a DC motor.
[0026]
Each of the first clutch 10 and the first motor (M1) 11 is electrically connected to a first motor controller (MC1) 13. The first motor controller (MC1) 13 is a device that controls the on / off and slip ratio of the first clutch 10 and the generated torque of the first motor (M1) 11, and includes, for example, an arithmetic processing circuit. (CPU) and a converter (inverter).
[0027]
The axle 15 of the left rear wheel 14 of the vehicle 1 is connected via a second clutch 16 to a motor shaft 18 of a second motor (M2) 17. The configuration of the second motor (M2) 17 is the same as that of the first motor (M1) 11.
[0028]
Each of the second clutch 16 and the second motor (M2) 17 is electrically connected to a second motor controller (MC2) 19. The second motor controller (MC2) 19 is a device that controls the on / off and slip ratio of the second clutch 16 and also controls the generated torque of the second motor (M2) 17. The configuration is the same as that of the motor controller (MC1) 13.
[0029]
A battery 20 is electrically connected to the first motor controller (MC1) 13 and the second motor controller (MC2) 19, and the first motor controller (MC1) 13 and the second motor controller (MC2) 19 A drive current can be applied from the battery 20 to each of the first motor (M1) 11 and the second motor (M2) 17.
[0030]
In the vehicle 1 configured as described above, an arithmetic logic operation circuit that integrally controls the operation state of the internal combustion engine 2 and the operation states of the first motor controller (MC1) 13 and the second motor controller (MC2) 19 (ECU) 21 is provided.
[0031]
The ECU 21 is electrically connected to the internal combustion engine 2, the transmission 3, the first motor controller (MC1) 13, the second motor controller (MC2) 19, and the battery 20.
[0032]
For example, the ECU 21 calculates a driving torque required for the vehicle 1 (hereinafter, referred to as a required driving torque), and calculates a driving torque required for each of the four wheels 4, 6, 8, and 14 from the required driving torque ( Hereinafter, the required driving torque for each wheel is calculated.
[0033]
As a method of calculating the required drive torque, a method of calculating the required drive torque using the operation amount of the accelerator pedal, the shift position of the transmission 3, the traveling speed (or the rotational speed of the wheels), and the like as parameters can be exemplified. .
[0034]
As a method of calculating the required drive torque for each wheel, the drive torque distribution ratio of the four wheels is determined by using the rotation speed of each wheel 4, 6, 8, and 14, the steering angle of the steering wheel, the acceleration of the vehicle 1, and the like as parameters. A method of determining the required drive torque for each wheel from the determined drive torque distribution ratio and the required drive torque can be exemplified.
[0035]
The ECU 21 controls the operating state of the internal combustion engine 2 and the gear ratio of the transmission 3 according to the required wheel-specific drive torque of the front wheels 4 and 6, and calculates the required wheel-specific drive torque of the right rear wheel 8 by a first motor controller (MC 1). 13 and the required drive torque for each wheel of the left rear wheel 14 is transmitted to the second motor controller (MC2) 19.
[0036]
The first motor controller (MC1) 13 controls the first clutch 10 and the first motor (M1) 11 according to the required driving torque for each wheel received from the ECU 21.
[0037]
For example, when the required drive torque for each wheel indicates a positive value, the ECU 21 couples the first clutch 10 and supplies a drive current corresponding to the required drive torque for each wheel to the first motor (M1) 11. To be applied.
[0038]
On the other hand, when the required driving torque for each wheel indicates a negative value, the ECU 21 couples the first clutch 10 and supplies an exciting current corresponding to the required driving torque for each wheel to the first motor (M1) 11. By operating the first motor (M1) 11 as a generator, regenerative power generation that converts the kinetic energy of the right rear wheel 8 into electric energy is performed.
[0039]
When the required driving torque for each wheel is “0”, the ECU 21 disconnects the first clutch 10 and stops the application of the driving current and the excitation current to the first motor (M1) 11.
[0040]
The second motor controller (MC2) 19, like the first motor controller (MC1) 13 described above, controls the second clutch 16 and the second motor (M2) 17 according to the required wheel-specific drive torque received from the ECU 21. Control.
[0041]
By the way, when the first motor controller (MC1) 13 or the second motor controller (MC2) 19 has an abnormality, the harmony between the driving torque of the right rear wheel 8 and the driving torque of the left rear wheel 14 is disturbed. Therefore, the running stability of the vehicle 1 may be reduced.
[0042]
On the other hand, in the present embodiment, the first motor controller (MC1) 13 and the second motor controller (MC2) 19 are connected via a communication line, and the first motor controller (MC1) 13 and the second motor controller (MC1) 13 are connected to each other. The second clutch 16 is electrically connected, and the second motor controller (MC2) 19 and the first clutch 10 are connected via electric wiring. Each of the ECU 21, the first motor controller (MC1) 13, and the second motor controller (MC2) 19 has a mutual monitoring function, and can determine an abnormality of each other.
[0043]
However, the abnormality determination function of the first motor controller (MC1) 13 and the second motor controller (MC2) 19 may be integrated with the abnormality determination function of the ECU 21, or the abnormality determination function of the ECU 21 may be replaced by the first. The motor controller (MC1) 13 and / or the second motor controller (MC2) 19 may be integrated with the abnormality determination function.
[0044]
The first motor controller (MC1) 13 and the second motor controller (MC2) 19 execute the following fail control when judging the abnormality of each other.
[0045]
First, the first motor controller (MC1) 13 executes a first fail control routine as shown in FIG. The first fail control routine is stored in, for example, a storage device provided in the first motor controller (MC1) 13, and is executed by the first motor controller (MC1) 13 as an interrupt process at regular time intervals. It is a routine to do.
[0046]
In the first fail control routine, the first motor controller (MC1) 13 first determines in step S201 whether the second motor controller (MC2) 19 is abnormal.
[0047]
As a method of determining whether or not the second motor controller (MC2) 19 is abnormal, the required drive torque for each wheel transmitted from the ECU 21 to the second motor controller (MC2) 19 and the second motor controller (MC2) MC2) 19 and the drive current applied to the second motor (M2) 17 is monitored, and the drive current does not correspond to the required drive torque for each wheel, and the drive current is fixed to a constant value. Under the condition that the second motor controller (MC2) 19 is abnormal.
[0048]
If it is determined in step S201 that the second motor controller (MC2) 19 is normal, the first motor controller (MC1) 13 proceeds to step S210, where the first clutch 10 and the first motor (MC1) M1) Control 11 as usual.
[0049]
On the other hand, if it is determined in S201 that the second motor controller (MC2) 19 is abnormal, the first motor controller (MC1) 13 proceeds to S202, and the second motor controller (MC2) 19 Is notified to the ECU 21 and the fail-safe control is executed in S203 to S209.
[0050]
In this case, a warning light or the like may be provided in the room of the vehicle 1 and the ECU 21 may light the warning light.
[0051]
In S203, the first motor controller (MC1) 13 determines whether or not the second motor (M2) 17 is operating as a motor, that is, whether the second motor controller (MC2) 19 has the second motor (MC2). M2) It is determined whether or not an abnormality has occurred while the motor 17 is operated as a motor.
[0052]
For example, the first motor controller (MC1) 13 outputs the second motor (M2) 17 if the required driving torque for each wheel transmitted from the ECU 21 to the second motor controller (MC2) 19 indicates a positive value. Is operating as a motor.
[0053]
If it is determined in S203 that the second motor (M2) 17 is operating as a motor, the first motor controller (MC1) 13 proceeds to S204.
[0054]
In S204, the first motor controller (MC1) 13 reads the required drive torque for each wheel: TqrM2 transmitted from the ECU 21 to the second motor controller (MC2) 19, and reads the required drive torque TqrM2 from the second motor controller (MC2) 19. An actual torque of the second motor (M2) 17 (hereinafter, referred to as an actual torque): TqM2 is calculated based on the drive current value applied to the second motor (M2) 17. Subsequently, the first motor controller (MC1) 13 determines whether the required driving torque per wheel: TqrM2 is smaller than the actual torque: TqM2.
[0055]
If it is determined in S204 that the required driving torque per wheel: TqrM2 is smaller than the actual torque: TqM2, the first motor controller (MC1) 13 proceeds to S205.
[0056]
In S205, the first motor controller (MC1) 13 sets the second clutch so that the torque transmitted from the second motor (M2) 17 to the left rear wheel 14 matches the wheel-specific required drive torque: TqrM2. The slip control of No. 16 is performed.
[0057]
For example, the first motor controller (MC1) 13 increases the slip ratio as the deviation between the required driving torque for each wheel: TqrM2 and the actual torque: TqM2 increases, and the required driving torque for each wheel: TqrM2 and the actual torque: TqM2. Is smaller, the slip ratio is lower. However, when the deviation between the required driving torque per wheel: TqrM2 and the actual torque: TqM2 becomes excessively large, the first motor controller (MC1) 13 interrupts the slip control of the second clutch 16 even if the first motor controller (MC1) 13 interrupts the slip control. Good.
[0058]
When the slip control of the second clutch 16 is performed as described above, the power transmission rate of the second clutch 16 decreases, and thus the torque transmitted from the second motor (M2) 17 to the left rear wheel 14 is reduced to the aforementioned value. Required driving torque for each wheel: TqrM2.
[0059]
As a result, the drive torque of the right rear wheel 8 and the drive torque of the left rear wheel 14 are harmonized, so that a decrease in the running stability of the vehicle 1 is suppressed.
[0060]
When it is determined in S204 that the required driving torque per wheel: TqrM2 is equal to or less than the actual torque: TqM2, the first motor controller (MC1) 13 proceeds to S206, and the required driving torque per wheel: TqrM2. And whether the actual torque is equal to TqM2.
[0061]
If it is determined in S206 that the required drive torque for each wheel: TqrM2 is equal to the actual torque: TqM2, the first motor controller (MC1) 13 sets the power transmission rate of the second clutch 16 to 100%. The second clutch 16 is connected as described above, and the execution of this routine is temporarily terminated.
[0062]
In this case, the driving torque of the left rear wheel 14 matches the required driving torque for each wheel: TqrM2. As a result, the drive torque of the right rear wheel 8 and the drive torque of the left rear wheel 14 are harmonized, so that a decrease in the running stability of the vehicle 1 is suppressed.
[0063]
If it is determined in S206 that the required driving torque for each wheel: TqrM2 is not equal to the actual torque: TqM2, that is, if the required driving torque for each wheel: TqrM2 is larger than the actual torque: TqM2, the first The motor controller (MC1) 13 proceeds to S207.
[0064]
In S207, the first motor controller (MC1) 13 executes the slip control of the second clutch 16. For example, the first motor controller (MC1) 13 gradually increases the slip ratio of the second clutch 16, and finally disconnects the second clutch 16.
[0065]
In S208, the first motor controller (MC1) 13 disconnects the first clutch 10 and controls the first motor (M1) 11 to stop the operation of the first motor (M1) 11 from the battery 20. The application of the driving current is stopped.
[0066]
In this case, since both the drive torque of the right rear wheel 8 and the drive torque of the left rear wheel 14 are “0”, the drive torques of the right rear wheel 8 and the left rear wheel 14 are harmonized. Further, when the second clutch 16 is disengaged, the slip ratio of the second clutch 16 is gradually increased, so that the driving torque of the left rear wheel 14 does not suddenly change.
[0067]
As described above, when the first clutch 10 and the second clutch 16 are disengaged, the ECU 21 reduces the required driving torque for each wheel to distribute the required driving torque of the vehicle 1 to only the right front wheel 4 and the left front wheel 6. Calculated values may be used to control the operating state of the internal combustion engine 2 and the gear ratio of the transmission 3 according to the required driving torque for each wheel.
[0068]
In this case, the vehicle 1 runs with only the torque generated by the internal combustion engine 2. That is, the vehicle 1 is driven by the right front wheel 4 and the left front wheel 6. As a result, the drive torques of the four wheels (the front right wheel 4, the front left wheel 6, the rear right wheel 8, and the rear left wheel 14) of the vehicle 1 are harmonized, thereby suppressing a decrease in the running stability of the vehicle 1. Is done.
[0069]
Further, when it is determined in S203 that the second motor (M2) 17 is not operating as a motor, in other words, when the second motor (M2) 17 is in an operation stop state, or Motor (M2) 17 is operating as a generator, the first motor controller (MC1) 13 proceeds to S209.
[0070]
In step S209, the first motor controller (MC1) 13 disconnects the first clutch 10 and the second clutch 16 and disconnects the first motor (M1) 11 from the battery 20 to stop the operation of the first motor (M1) 11. The application of the drive current to the motor (M1) 11 is stopped.
[0071]
In this case, since both the drive torque of the right rear wheel 8 and the drive torque of the left rear wheel 14 are “0”, the drive torques of the right rear wheel 8 and the left rear wheel 14 are harmonized.
[0072]
In this way, the first motor controller (MC1) 13 executes the first fail control routine, so that even if an abnormality occurs in the second motor controller (MC2) 19, the right rear wheel 8 And the driving torque of the left rear wheel 14 is harmonized, so that a decrease in the running stability of the vehicle 1 is suppressed.
[0073]
Next, the second motor controller (MC2) 19 executes a fail control routine as shown in FIG. This fail control routine is, for example, a routine that is stored in a storage device provided in the second motor controller (MC2) 19 and executed by the second motor controller (MC2) 19 as an interruption process at regular time intervals. is there.
[0074]
In the second fail control routine, first, in S301, the second motor controller (MC2) 19 determines whether or not the first motor controller (MC1) 13 is abnormal.
[0075]
If it is determined in S301 that the first motor controller (MC1) 13 is normal, the second motor controller (MC2) 19 proceeds to S310, where the second clutch 16 and the second motor (MC2) M2) Control 17 as usual.
[0076]
On the other hand, if it is determined in S301 that the first motor controller (MC1) 13 is abnormal, the second motor controller (MC2) 19 proceeds to S302, and the first motor controller (MC1) 13 Is notified to the ECU 21 and the fail-safe control is executed in S303 to S309.
[0077]
In this case, a warning light or the like may be provided in the room of the vehicle 1 and the ECU 21 may light the warning light.
[0078]
In S303, the second motor controller (MC2) 19 determines whether or not the first motor (M1) 11 is operating as a motor, that is, whether the first motor controller (MC1) 13 has the first motor (MC1). M1) It is determined whether or not an abnormality has occurred while the motor 11 is operated as a motor.
[0079]
If it is determined in S303 that the first motor (M1) 11 is operating as a motor, the second motor controller (MC2) 19 proceeds to S304.
[0080]
In S304, the second motor controller (MC2) 19 reads the required drive torque for each wheel: TqrM1 transmitted from the ECU 21 to the first motor controller (MC1) 13, and reads the first motor controller (MC1) 13 from the first motor controller (MC1) 13. Based on the drive current value applied to the first motor (M1) 11, an actual torque (hereinafter, referred to as an actual torque): TqM1 of the first motor (M1) 11 is calculated. Subsequently, the second motor controller (MC2) 19 determines whether the required driving torque per wheel: TqrM1 is smaller than the actual torque: TqM1.
[0081]
If it is determined in S304 that the required driving torque per wheel: TqrM1 is smaller than the actual torque: TqM1, the second motor controller (MC2) 19 proceeds to S305.
[0082]
In S305, the second motor controller (MC2) 19 controls the first clutch so that the torque transmitted from the first motor (M1) 11 to the right rear wheel 8 matches the wheel-specific required drive torque: TqrM1. 10 slip control is performed.
[0083]
For example, the second motor controller (MC2) 19 increases the slip ratio as the deviation between the required driving torque for each wheel: TqrM1 and the actual torque: TqM1 increases, and the required driving torque for each wheel: TqrM1 and the actual torque: TqM1. Is smaller, the slip ratio is lower.
[0084]
When the slip control of the first clutch 10 is performed as described above, the power transmission rate of the first clutch 10 decreases, so that the torque transmitted from the first motor (M1) 11 to the right rear wheel 8 Required driving torque for each wheel: TqrM1.
[0085]
As a result, the drive torque of the right rear wheel 8 and the drive torque of the left rear wheel 14 are harmonized, so that a decrease in the running stability of the vehicle 1 is suppressed.
[0086]
If it is determined in S304 that the required driving torque per wheel: TqrM1 is equal to or less than the actual torque: TqM1, the second motor controller (MC2) 19 proceeds to S306, and the required driving torque per wheel: TqrM1. And the actual torque: TqM1 are determined.
[0087]
If it is determined in S306 that the required driving torque per wheel: TqrM1 is equal to the actual torque: TqM1, the second motor controller (MC2) 19 sets the power transmission rate of the first clutch 10 to 100%. The first clutch 10 is connected as described above, and the execution of this routine is temporarily terminated.
[0088]
In this case, the driving torque of the right rear wheel 8 matches the required driving torque for each wheel: TqrM1. As a result, the drive torque of the right rear wheel 8 and the drive torque of the left rear wheel 14 are harmonized, so that a decrease in the running stability of the vehicle 1 is suppressed.
[0089]
If it is determined in S306 that the required driving torque per wheel: TqrM1 is not equal to the actual torque: TqM1, that is, if the required driving torque per wheel: TqrM1 is greater than the actual torque: TqM1, the second motor controller (MC2) 19 proceeds to S307.
[0090]
In S307, the second motor controller (MC2) 19 performs the slip control of the first clutch 10. Specifically, the second motor controller (MC2) 19 gradually increases the slip ratio of the first clutch 10 and finally disconnects the first clutch 10.
[0091]
In S308, the second motor controller (MC2) 19 disconnects the second clutch 16 and stops the operation of the second motor (M2) 17 from the battery 20 to the second motor (M2) 17. The application of the driving current is stopped.
[0092]
In this case, since both the drive torque of the right rear wheel 8 and the drive torque of the left rear wheel 14 are “0”, the drive torques of the right rear wheel 8 and the left rear wheel 14 are harmonized. Furthermore, when the first clutch 10 is disengaged, the slip ratio of the first clutch 10 is gradually increased, so that the driving torque of the right rear wheel 8 does not change abruptly.
[0093]
As described above, when the first clutch 10 and the second clutch 16 are disengaged, the ECU 21 reduces the required driving torque for each wheel to distribute the required driving torque of the vehicle 1 to only the right front wheel 4 and the left front wheel 6. Calculated values may be used to control the operating state of the internal combustion engine 2 and the gear ratio of the transmission 3 according to the required driving torque for each wheel.
[0094]
In this case, the vehicle 1 runs with only the torque generated by the internal combustion engine 2. That is, the vehicle 1 is driven by the right front wheel 4 and the left front wheel 6. As a result, the drive torques of the four wheels (the front right wheel 4, the front left wheel 6, the rear right wheel 8, and the rear left wheel 14) of the vehicle 1 are harmonized, thereby suppressing a decrease in the running stability of the vehicle 1. Is done.
[0095]
In addition, when it is determined in S303 that the first motor (M1) 11 is not operating as a motor, in other words, when the first motor (M1) 11 is in an operation stop state, If the motor (M1) 11 is operating as a generator, the second motor controller (MC2) 19 proceeds to S309.
[0096]
In S309, the second motor controller (MC2) 19 disconnects the first clutch 10 and the second clutch 16 from the battery 20 to stop the operation of the second motor (M2) 17 while disconnecting the first clutch 10 and the second clutch 16. The application of the drive current to the motor (M2) 17 is stopped.
[0097]
In this case, since both the drive torque of the right rear wheel 8 and the drive torque of the left rear wheel 14 are “0”, the drive torques of the right rear wheel 8 and the left rear wheel 14 are harmonized.
[0098]
As described above, by executing the second fail control routine by the second motor controller (MC2) 19, even if an abnormality occurs in the first motor controller (MC1) 13, the right rear wheel 8 can be controlled. And the driving torque of the left rear wheel 14 is harmonized, so that a decrease in the running stability of the vehicle 1 is suppressed.
[0099]
<Other embodiments>
In the above-described embodiment, the example in which the present invention is applied to the hybrid type four-wheel drive vehicle driven by the power of the internal combustion engine and the power of the motor has been described. The present invention may be applied to a four-wheel drive vehicle of the formula.
[0100]
FIG. 4 is a diagram showing a schematic configuration of an electric four-wheel drive vehicle. In FIG. 4, the same components as those in the above-described embodiment are denoted by the same reference numerals as those in the above-described embodiment.
[0101]
The axle 22 of the right front wheel 4 of the vehicle 1 is connected to a motor shaft 25 of a third motor (M3) 24 via a third clutch 23.
[0102]
Each of the third clutch 23 and the third motor (M3) 24 is electrically connected to a third motor controller (MC3) 26. The third motor controller (MC3) 26 has the same configuration as the first motor controller (MC1) 13 and the second motor controller (MC2) 19.
[0103]
The axle 27 of the left front wheel 6 of the vehicle 1 is connected to a motor shaft 30 of a fourth motor (M4) 29 via a fourth clutch 28.
[0104]
Each of the fourth clutch 28 and the fourth motor (M4) 29 is electrically connected to a fourth motor controller (MC4) 31. The fourth motor controller (MC4) 31 has the same configuration as the first motor controller (MC1) 13 and the second motor controller (MC2) 19.
[0105]
The first motor controller (MC1) 13, the second motor controller (MC2) 19, the third motor controller (MC3) 26, and the fourth motor controller (MC4) 31 are electrically connected to a battery (not shown). It is possible to apply a drive current from the battery to each of the first motor (M1) 11, the second motor (M2) 17, the third motor (M3) 24, and the fourth motor (M4) 29. Has become.
[0106]
The first motor controller (MC1) 13 and the fourth motor controller (MC4) 31 are connected via a communication line, and the second motor controller (MC2) 19 and the third motor controller (MC3) 26 Connected via a communication line.
[0107]
Further, the first motor controller (MC1) 13 is electrically connected to the fourth clutch 28, the second motor controller (MC2) 19 is electrically connected to the third clutch 23, and the third motor The controller (MC3) 26 is electrically connected to the second clutch 16, and the fourth motor controller (MC4) 31 is electrically connected to the first clutch 10.
[0108]
Each of first motor controller (MC1) 13, second motor controller (MC2) 19, third motor controller (MC3) 26, and fourth motor controller (MC4) 31 is electrically connected to ECU 21. Have been.
[0109]
Each of the first motor controller (MC1) 13 and the fourth motor controller (MC4) 31 has a mutual monitoring function, and is capable of determining each other's abnormality.
[0110]
Each of the second motor controller (MC2) 19 and the third motor controller (MC3) 26 is also provided with a mutual monitoring mechanism, so that it is possible to determine an abnormality of each other.
[0111]
In the vehicle 1 configured as described above, the first motor controller (MC1) 13,
And the fourth motor controller (MC4) 31 execute the following fail control.
[0112]
First, the first motor controller (MC1) 13 executes a first fail control routine as shown in FIG.
[0113]
In the first fail control routine, the first motor controller (MC1) 13 first determines in S501 whether the fourth motor controller (MC4) 31 is abnormal.
[0114]
If it is determined in S501 that the fourth motor controller (MC4) 31 is normal, the first motor controller (MC1) 13 proceeds to S510, where the first clutch 10 and the first motor (MC1) M1) Control 11 as usual.
[0115]
On the other hand, if it is determined in S501 that the fourth motor controller (MC4) 31 is abnormal, the first motor controller (MC1) 13 proceeds to S502, where the fourth motor controller (MC4) 31 Is notified to the ECU 21, and the fail-safe control is executed in S503 to S509.
[0116]
In this case, the ECU 21 may turn on a warning light or the like provided inside the vehicle 1.
[0117]
In S503, the first motor controller (MC1) 13 determines whether the fourth motor controller (MC4) 31 is operating as a motor, that is, the fourth motor controller (MC4) 31 (M4) It is determined whether an abnormality has occurred while the motor 29 is operated as a motor.
[0118]
If it is determined in S503 that the fourth motor controller (MC4) 31 is operating as a motor, the first motor controller (MC1) 13 proceeds to S504.
[0119]
In S504, the first motor controller (MC1) 13 reads the required driving torque for each wheel: TqrM4 transmitted from the ECU 21 to the fourth motor controller (MC4) 31, and reads the required motor torque from the fourth motor controller (MC4) 31. An actual torque: TqM4 of the fourth motor (M4) 29 is calculated based on the drive current value to the fourth motor (M4) 29. Subsequently, the first motor controller (MC1) 13 determines whether the required driving torque per wheel: TqrM4 is smaller than the actual torque: TqM4.
[0120]
If it is determined in S504 that the required driving torque per wheel: TqrM4 is smaller than the actual torque: TqM4, the first motor controller (MC1) 13 proceeds to S505.
[0121]
In S505, the first motor controller (MC1) 13 sets the fourth clutch so that the torque transmitted from the fourth motor controller (MC4) 31 to the left front wheel 6 matches the wheel-specific required drive torque: TqrM4. 28 is performed.
[0122]
For example, the first motor controller (MC1) 13 increases the slip ratio as the deviation between the required driving torque for each wheel: TqrM4 and the actual torque: TqM4 increases, and the required driving torque for each wheel: TqrM4 and the actual torque: TqM4. Is smaller, the slip ratio is lower.
[0123]
When the slip control of the fourth clutch 28 is performed as described above, the power transmission rate of the fourth clutch 28 decreases, so that the torque transmitted from the fourth motor (M4) 29 to the left front wheel 6 Another required drive torque: TqrM4.
[0124]
In this case, the harmony between the driving torque of the right rear wheel 8 and the driving torque of the left front wheel 6 is maintained. As a result, the driving torques of the four wheels arranged on the front, rear, left, and right sides of the vehicle 1 are harmonized, so that a decrease in the running stability of the vehicle 1 is suppressed.
[0125]
When it is determined in S504 that the required driving torque per wheel: TqrM4 is equal to or less than the actual torque: TqM4, the first motor controller (MC1) 13 proceeds to S506, and the required driving torque per wheel: TqrM4. And whether the actual torque is equal to TqM4.
[0126]
When it is determined in S506 that the required driving torque per wheel: TqrM4 is equal to the actual torque: TqM4, the first motor controller (MC1) 13 sets the power transmission rate of the fourth clutch 28 to 100%. The fourth clutch 28 is connected as described above, and the execution of this routine is temporarily terminated.
[0127]
In this case, the drive torque of the left front wheel 6 matches the required drive torque for each wheel: TqrM4. As a result, harmony between the drive torque of the right rear wheel 8 and the drive torque of the left front wheel 6 is maintained. As a result, the drive torques of the four wheels arranged on the front, rear, left, and right sides of the vehicle 1 are harmonized, so that a decrease in the running stability of the vehicle 1 is suppressed.
[0128]
If it is determined in S506 that the required driving torque for each wheel: TqrM4 is not equal to the actual torque: TqM4, that is, if the required driving torque for each wheel: TqrM4 is greater than the actual torque: TqM4, the first motor controller (MC1) 13 proceeds to S507.
[0129]
In S507, the first motor controller (MC1) 13 performs the slip control of the fourth clutch 28. For example, the first motor controller (MC1) 13 gradually increases the slip ratio of the fourth clutch 28 and finally disconnects the fourth clutch 28.
[0130]
In S508, the first motor controller (MC1) 13 disconnects the first clutch 10 and stops the operation of the first motor (M1) 11 from the battery 20 to the first motor (M1) 11. The application of the driving current is stopped.
[0131]
In this case, both the driving torque of the right rear wheel 8 and the driving torque of the left front wheel 6 become “0”. Further, when the fourth clutch 28 is disengaged, the slip ratio of the fourth clutch 28 is gradually increased, so that the driving torque of the left front wheel 6 does not suddenly change.
[0132]
When the drive torque of the right rear wheel 8 and the left front wheel 6 is set to “0” as described above, the ECU 21 allocates the required drive torque of the vehicle 1 to only the left rear wheel 14 and the right front wheel 4 by the respective wheels. The required drive torque may be calculated, and the required drive torque for each wheel may be transmitted to the second motor controller (MC2) 19 and the third motor controller (MC3) 26.
[0133]
The second motor controller (MC2) 19 and the third motor controller (MC3) 26 are configured to control the second clutch 16, the second motor (M2) 17, the third motor The clutch 23 and the third motor (M3) 24 are controlled.
[0134]
In this case, the vehicle 1 is driven by the right front wheel 4 and the left rear wheel 14. That is, the vehicle 1 is driven by two wheels arranged diagonally to the vehicle 1.
[0135]
As a result, in the vehicle 1, the drive torques of the front and rear wheels are harmonized, and the drive torques of the left and right wheels are also harmonized, thereby suppressing a decrease in the running stability of the vehicle.
[0136]
In addition, when it is determined in S503 that the fourth motor (M4) 29 is not operating as a motor, in other words, when the fourth motor (M4) 29 is in an operation stop state, or If the motor (M4) 29 is operating as a generator, the first motor controller (MC1) 13 proceeds to S509.
[0137]
In S509, the first motor controller (MC1) 13 disconnects the first clutch 10 and the fourth clutch 28, and outputs the first motor (M1) 11 from the battery 20 to stop the operation of the first motor (M1) 11. The application of the drive current to the motor (M1) 11 is stopped.
[0138]
In this case, both the driving torque of the right rear wheel 8 and the driving torque of the left front wheel 6 become “0”.
[0139]
When the drive torque of the right rear wheel 8 and the left front wheel 6 is set to “0” as described above, the ECU 21 allocates the required drive torque of the vehicle 1 to only the left rear wheel 14 and the right front wheel 4 by the respective wheels. The required drive torque may be calculated, and the required drive torque for each wheel may be transmitted to the second motor controller (MC2) 19 and the third motor controller (MC3) 26.
[0140]
The second motor controller (MC2) 19 and the third motor controller (MC3) 26 are configured to control the second clutch 16, the second motor (M2) 17, the third motor The clutch 23 and the third motor (M3) 24 are controlled.
[0141]
In this case, the vehicle 1 is driven by the right front wheel 4 and the left rear wheel 14. That is, the vehicle 1 is driven by two wheels arranged diagonally to the vehicle 1.
[0142]
As a result, in the vehicle 1, the drive torques of the front and rear wheels are harmonized, and the drive torques of the left and right wheels are also harmonized, thereby suppressing a decrease in the running stability of the vehicle.
[0143]
As described above, the first motor controller (MC1) 13 executes the first fail control routine, so that even if an abnormality occurs in the fourth motor controller (MC4) 31, the drive of the front and rear wheels is performed. Since the harmonization of the torque and the driving torque of the left and right wheels is achieved at the same time, a decrease in the running stability of the vehicle 1 is suppressed.
[0144]
Next, the fourth motor controller (MC4) 31 executes a fail control routine as shown in FIG.
[0145]
In the second fail control routine, the fourth motor controller (MC4) 31 first determines in step S601 whether the first motor controller (MC1) 13 is abnormal.
[0146]
If it is determined in step S601 that the first motor controller (MC1) 13 is normal, the fourth motor controller (MC4) 31 proceeds to step S610, where the fourth clutch 28 and the fourth motor (MC4) M4) Control 29 as usual.
[0147]
On the other hand, if it is determined in S601 that the first motor controller (MC1) 13 is abnormal, the fourth motor controller (MC4) 31 proceeds to S602, and the first motor controller (MC1) 13 After notifying the ECU 21 that the is abnormal, fail-safe control is executed in S603 to S609.
[0148]
In this case, the ECU 21 may turn on a warning light or the like provided inside the vehicle 1.
[0149]
In S603, the fourth motor controller (MC4) 31 determines whether or not the first motor (M1) 11 is operating as a motor, that is, the first motor controller (MC1) 13 M1) It is determined whether or not an abnormality has occurred while the motor 11 is operated as a motor.
[0150]
If it is determined in step S603 that the first motor (M1) 11 is operating as a motor, the fourth motor controller (MC4) 31 proceeds to step S604.
[0151]
In S604, the fourth motor controller (MC4) 31 reads the required driving torque for each wheel: TqrM1 transmitted from the ECU 21 to the first motor controller (MC1) 13, and reads the first motor controller (MC1) 13 from the first motor controller (MC1) 13. The actual torque TqM1 of the first motor (M1) 11 is calculated based on the drive current value applied to the first motor (M1) 11. Subsequently, the fourth motor controller (MC4) 31 determines whether the required driving torque per wheel: TqrM1 is smaller than the actual torque: TqM1.
[0152]
If it is determined in S604 that the required driving torque per wheel: TqrM1 is smaller than the actual torque: TqM1, the fourth motor controller (MC4) 31 proceeds to S605.
[0153]
In S605, the fourth motor controller (MC4) 31 transmits the first clutch so that the torque transmitted from the first motor (M1) 11 to the right rear wheel 8 matches the wheel-specific required drive torque: TqrM1. 10 slip control is performed.
[0154]
In this case, the harmony between the driving torque of the right rear wheel 8 and the driving torque of the left front wheel 6 is maintained. As a result, the driving torques of the four wheels arranged on the front, rear, left, and right sides of the vehicle 1 are harmonized, so that a decrease in the running stability of the vehicle 1 is suppressed.
[0155]
If it is determined in S604 that the required driving torque per wheel: TqrM1 is equal to or less than the actual torque: TqM1, the fourth motor controller (MC4) 31 proceeds to S606, and the required driving torque per wheel: TqrM1. And the actual torque: TqM1 are determined.
[0156]
If it is determined in S606 that the required driving torque per wheel: TqrM1 is equal to the actual torque: TqM1, the fourth motor controller (MC4) 31 sets the power transmission rate of the first clutch 10 to 100%. The first clutch 10 is connected as described above, and the execution of this routine is temporarily terminated.
[0157]
In this case, the driving torque of the right rear wheel 8 matches the required driving torque for each wheel: TqrM1. As a result, the drive torque of the right rear wheel 8 and the drive torque of the left front wheel 6 are harmonized, so that a decrease in the running stability of the vehicle 1 is suppressed.
[0158]
If it is determined in S606 that the required driving torque per wheel: TqrM1 is not equal to the actual torque: TqM1, that is, if the required driving torque per wheel: TqrM1 is greater than the actual torque: TqM1, the fourth motor controller (MC4) 31 proceeds to S607.
[0159]
In S607, the fourth motor controller (MC4) 31 performs the slip control of the first clutch 10. Specifically, the fourth motor controller (MC4) 31 gradually increases the slip ratio of the first clutch 10 and finally disconnects the first clutch 10.
[0160]
In S608, the fourth motor controller (MC4) 31 disconnects the fourth clutch 28 and stops the operation of the fourth motor (M4) 29.
[0161]
In this case, both the driving torque of the right rear wheel 8 and the driving torque of the left front wheel 6 become “0”. Furthermore, when the first clutch 10 is disengaged, the slip ratio of the first clutch 10 is gradually increased, so that the driving torque of the right rear wheel 8 does not change abruptly.
[0162]
When the drive torque of the right rear wheel 8 and the left front wheel 6 is set to “0” as described above, the ECU 21 allocates the required drive torque of the vehicle 1 to only the left rear wheel 14 and the right front wheel 4 by the respective wheels. The required drive torque may be calculated, and the required drive torque for each wheel may be transmitted to the second motor controller (MC2) 19 and the third motor controller (MC3) 26.
[0163]
The second motor controller (MC2) 19 and the third motor controller (MC3) 26 are configured to control the second clutch 16, the second motor (M2) 17, the third motor The clutch 23 and the third motor (M3) 24 are controlled.
[0164]
In this case, the vehicle 1 is driven by the right front wheel 4 and the left rear wheel 14. That is, the vehicle 1 is driven by two wheels arranged diagonally to the vehicle 1.
[0165]
As a result, in the vehicle 1, the drive torques of the front and rear wheels are harmonized, and the drive torques of the left and right wheels are also harmonized, thereby suppressing a decrease in the running stability of the vehicle.
[0166]
When it is determined in S603 that the first motor (M1) 11 is not operating as a motor, in other words, when the first motor (M1) 11 is in an operation stop state, or If the motor (M1) 11 is operating as a generator, the fourth motor controller (MC4) 31 proceeds to S609.
[0167]
In S609, the fourth motor controller (MC4) 31 disconnects the first clutch 10 and the fourth clutch 28 and stops the operation of the fourth motor (M4) 29.
[0168]
In this case, since both the drive torque of the right rear wheel 8 and the drive torque of the left front wheel 6 are “0”, the ECU 21 distributes the required drive torque of the vehicle 1 only to the left rear wheel 14 and the right front wheel 4. In this case, the vehicle 1 is driven by the right front wheel 4 and the left rear wheel 14. That is, the vehicle 1 is driven by two wheels arranged diagonally to the vehicle 1.
[0169]
As a result, in the vehicle 1, the drive torques of the front and rear wheels are harmonized, and the drive torques of the left and right wheels are also harmonized, thereby suppressing a decrease in the running stability of the vehicle.
[0170]
As described above, the fourth motor controller (MC4) 31 executes the second fail control routine, so that even if an abnormality occurs in the first motor controller (MC1) 13, the front and rear wheels are driven. Since the harmonization of the torque and the driving torque of the left and right wheels is achieved at the same time, a decrease in the running stability of the vehicle 1 is suppressed.
[0171]
Further, each of the second motor controller (MC2) 19 and the third motor controller (MC3) 26 performs the same fail processing as the first motor controller (MC1) 13 and the fourth motor controller (MC4) 31 described above. Execute
[0172]
As described above, the first motor controller (MC1) 13, the second motor controller (MC2) 19, the third motor controller (MC3) 26, and the fourth motor controller (MC4) 31 Is executed, it is possible to suppress a decrease in running stability of the vehicle 1 even when an abnormality occurs in the motor controller of one of the four wheels.
[0173]
【The invention's effect】
In the vehicle control device according to the present invention, in a vehicle in which an electric motor, a power transmission mechanism, and a control device are provided in at least two drive wheels, when an abnormality occurs in one of the drive wheel control devices, When the drive wheel control device controls the power transmission mechanism of one drive wheel, it is possible to control the drive torque of one drive wheel.
[0174]
As a result, the drive torque of one drive wheel is harmonized with the drive torque of the other drive wheels, thereby suppressing a decrease in running stability of the vehicle.
[Brief description of the drawings]
FIG. 1 is a diagram showing a schematic configuration of a vehicle according to an embodiment.
FIG. 2 is a flowchart illustrating a first fail control routine;
FIG. 3 is a flowchart showing a second fail control routine;
FIG. 4 is a diagram showing a schematic configuration of a vehicle according to another embodiment.
FIG. 5 is a flowchart illustrating a first fail control routine according to another embodiment.
FIG. 6 is a flowchart illustrating a second fail control routine according to another embodiment.
[Explanation of symbols]
1 ... Vehicle
4 Right front wheel
6 ... Left front wheel
8 Right rear wheel
10. First clutch
11. First motor (M1)
13. First motor controller (MC1)
14. Left rear wheel
16. Second clutch
17. Second motor (M2)
19. Second motor controller (MC2)
21..ECU
23 .. The third clutch
24 .. Third motor (M3)
26 .. Third motor controller (MC3)
28. 4th clutch
29 .. Fourth motor (M4)
31. 4th motor controller (MC4)

Claims (5)

A plurality of wheels provided on the vehicle;
An electric motor provided on each of at least two drive wheels of the wheels,
A power transmission mechanism that changes a power transmission rate between the electric motor and the drive wheels;
A control device that is provided for each drive wheel and controls an electric motor and / or a power transmission mechanism of each drive wheel;
A failure processing unit that controls a power transmission mechanism of the one drive wheel by a control device of another drive wheel when an abnormality occurs in the control device of one of the drive wheels;
A vehicle control device comprising: The drive wheel is a front wheel or a rear wheel disposed on the left and right of the vehicle,
2. The failure processing means according to claim 1, wherein when an abnormality occurs in one of the drive wheels, the control device of the other drive wheel controls the power transmission mechanism of the one drive wheel. The vehicle control device according to claim 1. The drive wheels are wheels arranged on the front, rear, left and right of the vehicle,
The failure processing means is configured such that, when an abnormality occurs in the control device for one of the drive wheels, the control device for the other drive wheel located diagonally to the one drive wheel causes the one drive wheel to fail. The vehicle control device according to claim 1, wherein the power transmission mechanism is controlled. When the output of the electric motor of the one drive wheel is excessive compared to the electric motor of the other drive wheel, the fail processing means controls the one drive wheel by the control device of the other drive wheel. The vehicle control device according to any one of claims 1 to 3, wherein a power transmission rate of the power transmission mechanism is reduced. When the output of the electric motor of the one drive wheel is too small compared to the electric motor of the other drive wheel, the fail processing means controls the one drive wheel by the control device of the other drive wheel. The vehicle control device according to any one of claims 1 to 3, wherein power transmission by the power transmission mechanism is interrupted.

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