JP5347535B2 - Vehicle braking force control device and braking force control method - Google Patents

Description

  The present invention relates to a braking force control device and a braking force control method provided in a vehicle that decelerates by using, for example, engine braking due to engine friction or regenerative braking by a motor during deceleration.

Conventionally, as a control device provided in a vehicle that decelerates by engine braking or regenerative braking during deceleration, for example, there is a control device as described in Patent Document 1.
In the control device described in Patent Document 1, in order to always obtain a constant deceleration regardless of the amount of power stored in the battery and to improve the recovery efficiency of power generated by regenerative braking, according to the amount of power stored in the battery, Controls the state of the clutch interposed between the engine and the transmission.

  Specifically, when the amount of power stored in the battery is less than a predetermined value and the power generated by regenerative braking can be charged to the battery, the clutch is controlled to be released during regenerative braking. On the other hand, if the amount of electricity stored in the battery is greater than or equal to a predetermined value and power cannot be charged to the battery, that is, if regenerative braking cannot be performed, the clutch is controlled to be engaged and only the braking force generated by the engine brake is used. Decelerate the vehicle.

JP 2000-118246 A

  In the control device described in Patent Document 1, when the drive wheel is locked while the vehicle is decelerated by the braking force generated by the engine brake while the clutch is controlled to be in a connected state, this lock is used to drive the engine. The force is transmitted to the drive wheel to suppress it. The above-mentioned lock means that the vehicle is decelerated by the engine brake. For example, when driving on a low μ road, the braking force applied to the drive wheels by the engine brake increases and the vehicle is driven. It is a lock generated in the ring.

However, the engine is less responsive to the command value than the motor. For this reason, when the lock is suppressed by the driving force of the engine, it is difficult to immediately suppress the lock generated on the drive wheels, compared to the case where the lock is suppressed by the driving force of the motor.
The present invention has been made paying attention to the above-described problems, and is a vehicle capable of suppressing with high responsiveness the locking of drive wheels that occurs when the vehicle is decelerated only by engine braking. It is an object of the present invention to provide a braking force control device and a braking force control method.

In order to solve the above-described problem, the present invention detects the lock of the drive wheel when detecting the lock of the drive wheel during vehicle deceleration when the charged amount of the battery is equal to or more than a predetermined charged amount and braking force is generated by engine friction. The driving wheel is driven by controlling the operation to rotational drive. At this time, the torque generated by the rotational drive of the motor is controlled to be equal to or less than the friction of the engine. The motor is driven to rotate by electric power supplied from the battery.

According to the present invention, the driving wheel lock generated while the vehicle is decelerated only by engine braking due to engine friction is driven with the motor being driven to rotate, thereby suppressing the driving wheel with high responsiveness. Is possible. For this reason, it becomes possible to stabilize the behavior of the vehicle when the driving wheel is locked and to improve the steering stability of the vehicle.
In addition, since the torque generated by the rotational drive of the motor is controlled to be equal to or less than the friction of the engine, it is possible to prevent the running state of the vehicle from changing from the deceleration even if the motor is rotationally driven.

It is a top view of a vehicle provided with the braking force control device of the first embodiment, and shows a schematic configuration of the vehicle. It is a block diagram which shows the structure of a vehicle control controller. It is a block diagram which shows the structure of a motor control means. It is a flowchart which shows the process of a braking force control apparatus. It is a time chart which shows operation | movement of the vehicle provided with the braking force control apparatus. It is a flowchart which shows the process of the braking force control apparatus in the modification of 1st embodiment.

(First embodiment)
Hereinafter, a first embodiment of the present invention (hereinafter referred to as “the present embodiment”) will be described with reference to the drawings.
(Constitution)
First, the configuration of a vehicle braking force control device (hereinafter referred to as “braking force control device”) according to the present embodiment will be described with reference to FIGS. 1 to 4.
FIG. 1 is a top view of a vehicle C provided with the braking force control apparatus of the present embodiment, and is a diagram showing a schematic configuration of the vehicle C.
As shown in FIG. 1, a vehicle C including a braking force control device is a vehicle having an engine 1, a drive wheel 2, a motor 4, a driven wheel 6, an acceleration sensor 8, and a vehicle control controller 10. is there.

The engine 1 is an internal combustion engine, and has an engine drive shaft 12 that can be rotated by driving the engine 1.
The engine drive shaft 12 can be connected to the drive wheels 2 via the transmission 14 and the clutch 16. In addition, the description regarding the transmission 14 and the clutch 16 is mentioned later.
The drive wheels 2 are wheels driven by the engine 1 in a state where the engine drive shaft 12 is connected to the drive wheels 2 via the transmission 14 and the clutch 16. That is, the engine 1 forms a drive source capable of driving the drive wheels 2 in a state where the engine drive shaft 12 is connected to the drive wheels 2 via the transmission 14 and the clutch 16. In the present embodiment, the case where the driving wheels 2 are the left and right front wheels 2L and 2R will be described as an example.

Front wheel speed sensors 18L and 18R are provided on the drive wheels 2, that is, the left and right front wheels 2L and 2R, respectively.
Each front wheel speed sensor 18L, 18R detects the rotation state (number of rotations, rotation speed) of the corresponding left and right front wheels 2L, 2R, and outputs an information signal including the detected rotation state to the vehicle controller 10. .
The engine 1 is provided with an engine speed sensor 20.
The engine rotational speed sensor 20 detects the rotational speed of the engine 1 and outputs an information signal including the detected rotational speed to the vehicle controller 10.

Further, a throttle valve is interposed in the intake pipe (not shown) of the engine 1. The throttle valve adjusts the driving state (rotation speed, torque) of the engine 1 by adjusting and controlling the opening degree (throttle opening degree) according to the operation amount (depression amount) of the accelerator pedal 22 by the driver. .
When an operation by the driver is performed, the accelerator pedal 22 outputs an information signal including the operation amount to the vehicle controller 10.
The motor 4 is formed by a field winding type synchronous motor, for example, and is connected to a battery 26 via an inverter 24. The description regarding the inverter 24 and the battery 26 will be described later.

The motor 4 has a rotor (not shown) having a field coil and a stator (not shown) wound with a three-phase winding (armature coil) for generating a rotating magnetic field. ing.
The rotor has a rotatable motor drive shaft 28.
The motor drive shaft 28 is connected to the drive wheel 2 via the transmission 14, and a magnetic field generated by passing a current through a field coil of the rotor and a magnetic field generated from an armature coil wound around the stator. It is driven to rotate by the interaction. That is, the motor 4 forms a drive source that can drive the drive wheels 2 by rotational drive.

Further, when the rotor is rotated by an external force, the motor 4 generates an electromotive force at both ends of the armature coil due to the interaction of these magnetic fields, and performs a power generation operation. The electric power generated by the motor 4 can be stored in the battery 26 via the inverter 24.
Here, “when the rotor is rotated by an external force” means that the driving wheel 2 is rotated by an external force when the vehicle C is decelerated, such as when the vehicle C is braked, and this rotation is transmitted via the transmission 14. This is a case where the vehicle C is regeneratively braked by the motor 4 after being transmitted to the rotor. That is, the motor 4 can store the battery 26 by regenerative braking.

As described above, the motor 4 is configured to drive the driving wheel 2 by rotational driving and to store the battery 26 by regenerative braking.
The inverter 24 supplies the power generated by the motor 4 to the battery 26. Specifically, DC power generated by the motor 4 is converted into AC power such as three-phase AC, and supplied to the battery 26.
The inverter 24 controls electric power supplied from the battery 26 to the motor 4 based on a control signal output from the vehicle controller 10, and controls torque generated by the motor 4 being rotationally driven.
The battery 26 can store the power supplied from the inverter 24 and can supply the stored power to the inverter 24.

The transmission 14 includes a transmission that can change the gear ratio in a plurality of stages, and is interposed in a driving force transmission path between the engine 1, the motor 4, and the driving wheels 2. That is, the driving force generated by the engine 1 and the motor 4 is transmitted to the driving wheel 2 with the changed gear ratio. Note that the above gear ratio varies depending on a selection operation by the driver or control with reference to the vehicle speed or the like.
The transmission 14 also has a transmission rotation shaft 30 that is rotated by the driving force generated by the engine 1.

  The clutch 16 is formed by, for example, a wet multi-plate clutch, and is interposed in a driving force transmission path between the engine 1 and the left and right front wheels 2L and 2R. Specifically, it is interposed between the engine drive shaft 12 and the transmission rotation shaft 30. In the present embodiment, the clutch 16 as the fastening means is a wet multi-plate clutch, but is not limited to this, and the clutch 16 may be formed by, for example, a powder clutch or a pump-type clutch.

The clutch 16 includes an engine side disk 32 fixed to the engine drive shaft 12 and a transmission side disk 34 fixed to the transmission rotation shaft 30.
The engine side disk 32 is provided with an engine side disk speed sensor 36.
The engine-side disk rotation speed sensor 36 detects the rotation speed of the engine-side disk 32 and outputs an information signal including the detected rotation speed to the vehicle controller 10.

The transmission side disk 34 is provided with a transmission side disk rotation speed sensor 38.
The transmission-side disk rotation speed sensor 38 detects the rotation speed of the transmission-side disk 34 and outputs an information signal including the detected rotation speed to the vehicle controller 10.
Further, the clutch 16 enters a connected state or a released state in accordance with a clutch control command output by the vehicle controller 10. Here, there are two types of clutch control commands: a clutch connection command for setting the clutch 16 in a connected state and a clutch release command for setting the clutch 16 in a released state. In FIG. 1, the clutch 16 is shown in a released state.

  When the clutch 16 is in the connected state, the engine-side disc 32 and the transmission-side disc 34 are connected, and the engine drive shaft 12 and the transmission rotating shaft 30 are connected. The engine-side disk 32 and the transmission-side disk 34 are connected in a state where the engine-side disk 32 and the transmission-side disk 34 are connected while slipping, and between the engine-side disk 32 and the transmission. The side disk 34 is connected without slipping.

In this state, the engine drive shaft 12 is connected to the left and right front wheels 2L and 2R, and the driving force of the engine 1 is transmitted to the left and right front wheels 2L and 2R via the clutch 16 and the transmission 14. That is, when the clutch 16 is in the connected state, the driving force transmission path between the engine 1 and the driving wheel 2 is connected.
On the other hand, when the clutch 16 is in the released state, the engine-side disc 32 and the transmission-side disc 34 are separated from each other, and the connection between the engine drive shaft 12 and the transmission rotation shaft 30 is released. In this state, the driving wheel 2 is rotationally driven using only the driving force from the motor 4 as a driving source. That is, when the clutch 16 is in the released state, the driving force transmission path between the engine 1 and the driving wheels 2 is released.

  The driven wheel 6 is a wheel arranged offset from the driving wheel 2 in the vehicle front-rear direction. In the present embodiment, as described above, since the driving wheel 2 is the left and right front wheels 2L and 2R, the driven wheel 6 is the left and right rear wheels 6L and 6R. That is, the driven wheel 6 is a wheel arranged offset from the driving wheel 2 in the vehicle front-rear direction rearward. Unlike the present embodiment, when the driving wheels 2 are left and right rear wheels, the driven wheels 6 are left and right front wheels. That is, the driven wheel 6 is a wheel arranged offset from the driving wheel 2 forward in the vehicle longitudinal direction.

Rear wheel speed sensors 40L and 40R are provided on the driven wheels 6, that is, the left and right rear wheels 6L and 6R, respectively.
Each of the rear wheel speed sensors 40L and 40R detects the rotation state (the number of rotations and the rotation speed) of the corresponding left and right rear wheels 6L and 6R, and sends an information signal including the detected rotation state to the vehicle controller 10. Output.
The acceleration sensor 8 is a sensor that detects acceleration and deceleration of the vehicle C in the longitudinal direction of the vehicle, and is arranged near the center of gravity of the vehicle C.
The acceleration sensor 8 detects the acceleration and deceleration in the vehicle longitudinal direction of the vehicle C, and outputs an information signal including the detected acceleration and deceleration in the vehicle longitudinal direction to the vehicle controller 10.

Although not particularly illustrated, the left and right front wheels 2L, 2R and the left and right rear wheels 6L, 6R are each provided with a brake device.
Each brake device responds to a corresponding wheel by transmitting a brake hydraulic pressure adjusted in accordance with an operation amount (depression amount) of the brake pedal 42 by the driver from a hydraulic pressure source (not shown). Apply braking force to the wheels.
When an operation by the driver is performed, the brake pedal 42 outputs an information signal including the operation amount to the vehicle controller 10.
The vehicle controller 10 is formed by an arithmetic processing device such as a microcomputer, for example.

Next, the configuration of the vehicle controller 10 will be described using FIG. 2 with reference to FIG.
FIG. 2 is a block diagram illustrating a configuration of the vehicle controller 10.
As shown in FIG. 2, the vehicle controller 10 includes a required braking force detection means 44, a battery storage amount detection means 46, a braking force control means 48, an engine control means 50, a clutch control means 52, a lock Detection means 54 and motor control means 56 are provided.
The required braking force detection means 44 detects the amount of operation of the accelerator pedal 22 and the brake pedal 42 by the driver based on the information signal output by the accelerator pedal 22 and the brake pedal 42. Based on the detected operation amounts of the accelerator pedal 22 and the brake pedal 42, a braking force required by the driver (required braking force) is calculated.

Specifically, when the operation amount of the accelerator pedal 22 is reduced to “0” from the state in which the accelerator pedal 22 is operated, the required braking force is reduced to the braking force generated by the regenerative braking of the motor 4 or the engine The braking force generated by the brake is calculated.
Further, when the operation amount of the brake pedal 42 is increased from the state where the brake pedal 42 is not operated, that is, the operation amount of the brake pedal 42 is “0”, the required braking force is greater than the braking force by the engine brake. Is also determined to have increased. Then, the required braking force is calculated according to the operation amount of the brake pedal 42.

The requested braking force detection unit 44 that has calculated the requested braking force outputs an information signal including the calculation result to the braking force control unit 48. The required braking force is calculated by the required braking force detection means 44 when the vehicle C is traveling.
The battery storage amount detection means 46 acquires the storage amount (battery storage amount) for the battery 26 at a predetermined cycle. Then, an information signal including the acquired battery storage amount is output to the braking force control means 48.

The braking force control unit 48 generates an information signal for controlling the braking force generated when the vehicle C is decelerated based on the information signals output from the required braking force detection unit 44 and the battery storage amount detection unit 46. The generated information signal is output to the engine control means 50, the clutch control means 52, and the motor control means 56.
Here, the control of the braking force generated when the vehicle C decelerates controls the braking force generated by the engine 1, the connection state of the clutch 16, and the braking force generated by the motor 4 based on the required braking force and the amount of stored battery. Do it.

  As an example, when the required braking force is greater than or equal to the required braking force by the engine brake and the battery charge amount is greater than or equal to a predetermined charge amount, the engine 1, The motor 4 and the clutch 16 are controlled. This is a control for setting the clutch 16 in a connected state, controlling the torque generated by the engine 1 to a torque generating friction of the engine 1, and further reducing the regenerative torque of the motor 4.

Note that the predetermined power storage amount is set to, for example, a power storage amount that is reduced by several percent from the power storage amount in a state where the battery 26 is fully charged in consideration of safety.
The engine control means 50 inputs and outputs information signals with the engine 1. Furthermore, based on the information signal output from the braking force control means 48 and the engine 1, the driving state (rotation speed, torque, etc.) of the engine 1 is controlled.

The clutch control unit 52 outputs a clutch connection command or a clutch release command to the clutch 16 based on the information signals output from the braking force control unit 48 and the motor control unit 56.
The lock detection means 54 detects the lock of the drive wheels 2 based on information signals output from the front wheel speed sensors 18L and 18R and the rear wheel speed sensors 40L and 40R. Then, an information signal including the detection result is output to the motor control unit 56.

Specifically, the state where the rotational speed of the driving wheel 2 detected by the front wheel speed sensors 18L and 18R is less than the rotational speed of the driven wheel 6 detected by the rear wheel speed sensors 40L and 40R is detected as the driving wheel. 2 is detected.
The motor control means 56 is an information signal including a control command for controlling the operation of the motor 4 based on information signals output from various sensors such as the braking force control means 48, the lock detection means 54, and the engine speed sensor 20. Is generated. Then, the generated information signal is output to the inverter 24. The various sensors are the engine speed sensor 20, the acceleration sensor 8, the front wheel speed sensors 18L and 18R, the rear wheel speed sensors 40L and 40R, the engine side disk speed sensor 36, and the transmission side disk speed. This is a sensor 38.
Moreover, the motor control means 56 produces | generates the information signal containing the control command for controlling the connection state of the clutch 16 by the process performed internally. The generated information signal is output to the clutch control means 52.

Hereinafter, the detailed configuration of the motor control means 56 will be described with reference to FIG.
FIG. 3 is a block diagram showing the configuration of the motor control means 56.
As shown in FIG. 3, the motor control means 56 includes friction calculation means 58, inertia torque calculation means 60, and rotational drive torque calculation means 62. Further, the motor control means 56 includes a deceleration detection means 64, a deceleration determination means 66, and a rotational drive torque correction means 68. In addition, the motor control means 56 includes a rotation deviation detection means 70, a half clutch determination means 72, and a motor torque control means 74.

The friction calculation unit 58 calculates the friction of the engine 1 based on the information signal output from the engine speed sensor 20. Then, an information signal including the calculated friction is output to the rotational drive torque calculation means 62 and the motor torque control means 74.
Here, the calculation of the friction of the engine 1 is performed based on the rotation speed of the engine 1 included in the information signal output from the engine rotation speed sensor 20. This is performed, for example, by detecting the speed at which the rotational speed of the engine 1 decreases when the engine 1 in the driving state is stopped, and referring to the degree of decrease in the speed. In this case, the speed at which the rotational speed decreases when the engine 1 is deteriorated before being deteriorated may be stored, and the friction when the engine 1 has deteriorated may be calculated using the stored speed. .

The inertia torque calculating means 60 calculates the inertia torque of the engine 1, the drive wheel 2 and the transmission 14 based on the information signals output from the engine speed sensor 20 and the front wheel speed sensors 18L and 18R, respectively. Then, an information signal including each calculated inertial torque is output to the rotational drive torque calculating means 62.
Here, the inertia torque of the engine 1 is calculated based on the engine speed included in the information signal output from the engine speed sensor 20. Further, the inertia torque of the drive wheels 2 is calculated based on the rotational speeds of the left and right front wheels 2L, 2R included in the information signals output from the front wheel speed sensors 18L, 18R. In addition, the inertia torque of the transmission 14 is the rotation of the left and right front wheels 2L and 2R, which is included in the rotation speed of the engine 1 included in the information signal output from the engine rotation speed sensor 20 and the information signal output from the front wheel speed sensors 18L and 18R. Calculate based on speed.

  The rotational drive torque calculating means 62 is a torque generated by rotational driving of the motor 4 based on information signals output from the friction calculating means 58, the inertia torque calculating means 60, the front wheel speed sensors 18L and 18R, and the rear wheel speed sensors 40L and 40R. Is calculated. Then, an information signal including the calculated torque is output to the motor torque control means 74.

  Here, the calculation of the torque generated by the rotational drive of the motor 4 includes the friction of the engine 1 included in the information signal output from the friction calculation means 58, the engine 1 included in the information signal output from the inertia torque calculation means 60, and the drive wheels 2 And based on the inertia torque of the transmission 14. In addition to this, the calculation of the torque generated by the rotational drive of the motor 4 is detected from the vehicle speed calculated from the wheel speeds output by the front wheel speed sensors 18L, 18R and the rear wheel speed sensors 40L, 40R, and the deviations of the wheel speeds. This is based on the slipping amount of the wheel. Note that the slip amount of the wheel is detected from the rotation speed when it is determined that the wheel is slipping, for example, when a wheel having a higher rotation speed than other wheels is detected.

  The deceleration detection means 64 detects the deceleration when the vehicle C is decelerated based on the information signal output from the acceleration sensor 8. Then, an information signal including the detected deceleration is output to the deceleration determining means 66. Specifically, the deceleration of the vehicle C forward of the vehicle included in the information signal output from the acceleration sensor 8 is detected, and the information signal including the detected deceleration is output to the deceleration determining means 66.

  The deceleration determination means 66 is based on the predetermined deceleration stored in advance and the information signal output by the deceleration detection means 64 and the motor torque control means 74. The deceleration of the vehicle C during deceleration is less than the predetermined deceleration. It is determined whether or not. This determination is performed when the information signal output from the motor torque control means 74 is an information signal including a control command for calculating the torque generated by the rotation drive of the motor 4 and generating this torque. Then, the deceleration determination unit 66 outputs an information signal including the determination result to the rotational drive torque correction unit 68.

Here, the above-mentioned “predetermined deceleration” is set to the minimum value of deceleration at which the driving state of the vehicle C does not become power running during deceleration, for example, and is stored in the deceleration determination means 66. .
The rotation drive torque correction means 68 generates an information signal for correcting the torque controlled by the motor torque control means 74 based on the information signal output from the deceleration determination means 66, and uses the generated information signal as the motor torque control means. Output to 74.

Specifically, when the information signal output by the deceleration determination means 66 includes a determination result that the deceleration of the vehicle C during deceleration is less than a predetermined deceleration, the torque generated by the motor 4 due to rotational driving An information signal including a command to weaken the signal at a predetermined rate is generated. The generated information signal is output to the motor torque control means 74.
The rotation deviation detecting means 70 detects a deviation between the rotation state of the driving wheel 2 and the rotation state of the driven wheel 6 based on information signals output from the front wheel speed sensors 18L and 18R and the rear wheel speed sensors 40L and 40R. Then, an information signal including the detected deviation is output to the motor torque control means 74.

In the present embodiment, the rotational state of the driving wheel 2 is the rotational speed of the driving wheel 2, and the rotational state of the driven wheel 6 is the rotational speed of the driven wheel 6.
The half-clutch determination means 72 determines whether or not the clutch 16 is connected while slipping, based on information signals output from the engine-side disk rotation speed sensor 36 and the transmission-side disk rotation speed sensor 38. This determination is performed when the clutch 16 is in a connected state, such as when a clutch connection command is output from the clutch control means 52 to the clutch 16. Then, the half-clutch determination unit 72 outputs an information signal including the determination result to the motor torque control unit 74.

  Specifically, based on the information signals output from the engine-side disk rotational speed sensor 36 and the transmission-side disk rotational speed sensor 38, the rotational speed of the engine-side disk rotational speed sensor 36 and the transmission-side disk rotational speed. The number of revolutions of the number sensor 38 is compared. When the rotational speed of the transmission-side disk rotational speed sensor 38 is faster than the rotational speed of the engine-side disk rotational speed sensor 36, it is determined that the clutch 16 is connected while slipping. On the other hand, when the rotational speed of the transmission-side disk rotational speed sensor 38 is the same as the rotational speed of the engine-side disk rotational speed sensor 36, it is determined that the clutch 16 is connected without slipping.

The motor torque control unit 74 is configured to rotate the motor 4 based on the information signals output from the friction calculation unit 58, the rotation drive torque calculation unit 62, the rotation drive torque correction unit 68, the rotation deviation detection unit 70, and the half clutch determination unit 72. The torque generated by is controlled.
Specifically, information including a control command for calculating the torque generated by the rotational drive of the motor 4 so as to cancel out the friction of the engine 1 included in the information signal output by the friction calculation means 58 and generating this torque. Generate a signal. The generated information signal is output to the inverter 24 and the deceleration determination means 66.

  Here, the deceleration determination unit 66 that has received the information signal output from the motor torque control unit 74 determines whether or not the deceleration of the vehicle C during deceleration is less than a predetermined deceleration. When it is determined that the deceleration of the vehicle C at the time of deceleration is less than the predetermined deceleration, the rotational drive torque correction means 68 includes information including a command for weakening the torque generated by the rotational drive of the motor 4 at a predetermined ratio. A signal is generated and output to the motor torque control means 74.

Upon receiving the information signal output from the rotational drive torque correction means 68, the motor torque control means 74 generates an information signal including a control command for weakening the torque calculated to cancel the friction of the engine 1 at a predetermined rate. To do. The generated information signal is output to the inverter 24 and the deceleration determination means 66.
The generation of the information signal including the command to weaken the torque generated by the rotational drive of the motor 4 at a predetermined rate by the rotational drive torque correction unit 68 described above is performed by the deceleration determination unit 66 using the deceleration of the vehicle C during deceleration. Is performed until it is determined that the speed is not less than the predetermined deceleration.

The motor torque control means 74 includes a feedback control means 76 and a gain switching means 78.
The feedback control means 76 stores two kinds of feedback gains and a predetermined deviation in advance. Based on the predetermined deviation and the information signal output from the rotation deviation detecting means 70, the motor 4 feedback controls the torque generated by the rotational drive. The predetermined deviation is set according to, for example, the performance of the motor 4.

The feedback gain is a gain used for feedback control.
The two types of feedback gains are a first gain and a second gain set in advance, and the second gain is a value smaller than the first gain.
Specifically, it is determined whether or not the deviation between the rotation speed of the drive wheel 2 and the rotation speed of the driven wheel 6 included in the information signal output from the rotation deviation detection means 70 is equal to or greater than a predetermined deviation. When the deviation between the rotational speed of the drive wheel 2 and the rotational speed of the driven wheel 6 is equal to or greater than a predetermined deviation, feedback control is performed on the torque generated by the motor 4 being rotationally driven.

The feedback control unit 76 outputs an information signal indicating that feedback control is being performed to the clutch control unit 52 while the feedback control is performed on the torque generated by the motor 4 being rotationally driven (during feedback control). To do.
Here, the clutch control means 52 that has received the input of the information signal indicating that feedback control is being performed outputs the clutch connection command or the clutch release command to the clutch 16 while the information signal is being input. Stop. That is, the clutch control means 52 does not output a clutch engagement command or a clutch release command during feedback control.

The gain switching unit 78 generates an information signal including a control command for switching between two types of feedback gains based on the information signal output from the half-clutch determination unit 72. The generated information signal is output to the feedback control means 76.
Specifically, when the information signal output from the half-clutch determination means 72 includes a determination result that the clutch 16 is engaged while slipping, an information signal including a control command for switching the feedback gain to the first gain is output. Generate. The generated information signal is output to the feedback control means 76.
On the other hand, when the information signal output from the half-clutch determination means 72 includes a determination result that the clutch 16 is connected without slipping, an information signal including a control command for switching the feedback gain to the second gain is generated. . The generated information signal is output to the feedback control means 76.

Hereinafter, processing performed by the braking force control apparatus will be specifically described with reference to FIGS. 1 to 3 and FIG.
FIG. 4 is a flowchart showing processing of the braking force control device.
The flowchart shown in FIG. 4 starts from a state in which the vehicle C is traveling (START).
When the vehicle C is traveling, the required braking force detection means 44 detects the amount of operation of the accelerator pedal 22 and the brake pedal 42 by the driver. Then, based on the requested braking force calculated based on the detected operation amount, the braking force control means 48 determines whether or not there is a deceleration request from the driver (“Is there a deceleration request?” Shown in FIG. 4). (Step S10).

Here, for example, when the operation amount of the accelerator pedal 22 is “0” or when the operation amount of the brake pedal 42 exceeds “0”, there is a required braking force, that is, a deceleration request from the driver. It is determined that there is.
If the braking force control means 48 determines in step S10 that there is no deceleration request from the driver ("No" shown in the figure), the processing performed by the braking force control device returns to the processing in step S10 (RETURN). To do.

On the other hand, in step S10, the braking force control means 48 that has determined that there is a deceleration request from the driver (“Yes” shown in the figure) further refers to the battery charge amount acquired by the battery charge amount detection means 46. . Then, it is determined whether or not the battery power storage amount is equal to or greater than a predetermined power storage amount (“power storage amount greater than or equal to a predetermined value?” Shown in FIG. 4) (step S12).
In step S12, when the braking force control unit 48 determines that the battery storage amount is less than the predetermined storage amount ("No" shown in the figure), the braking force control unit 48 sends the clutch control unit 52 to the clutch 16; A control command for releasing is output. Receiving this control command, the clutch control means 52 outputs a clutch release command to the clutch 16, and puts the clutch 16 into a released state ("clutch off" shown in FIG. 4) (step S14).

  When the clutch 16 is in the released state in step S <b> 14, the braking force control unit 48 outputs an information signal for controlling the braking force generated when the vehicle C is decelerated to the motor control unit 56. Upon receiving this information signal, the motor control means 56 can generate the regenerative torque of the motor 4 to generate a braking force required when the vehicle C is decelerated, and can store the electric power generated by the motor 4 in the battery 26. An information signal to be controlled is output to the inverter 24. As a result, the deceleration force of the vehicle C is controlled by the braking force generated by the regenerative torque of the motor 4 ("motor regeneration deceleration force control" shown in the figure), and the electric power generated by the regeneration of the motor 4 is stored in the battery 26. (Step S18).

When the regenerative torque of the motor 4 is controlled in step S18, the motor control means 56 determines whether or not slip has occurred due to the lock of the drive wheels 2 based on the information signal output from the lock detection means 54 (in the figure). ("Slip?") (Step S20).
If the motor control means 56 determines in step S20 that no slip has occurred due to the lock of the drive wheels 2 ("No" shown in the figure), the processing performed by the braking force control device returns to the processing in step S10. (RETURN).

  On the other hand, in step S20, the motor control means 56, which has determined that slip has occurred due to the lock of the drive wheel 2 ("Yes" shown in the figure), the operation of the motor 4 so as to suppress the lock of the drive wheel 2. Is output to the inverter 24. Thereby, the driving wheel 2 is driven by the regenerative torque generated by the motor 4 or the torque generated by the rotational driving of the motor 4 to suppress the slip generated by the locking of the driving wheel 2 (the “motor shown in the figure” Slip control ") (step S22).

When the operation of the motor 4 is controlled so as to suppress the lock of the drive wheels 2, the process performed by the braking force control device returns to the process of step S10 (RETURN).
On the other hand, in step S12, the braking force control unit 48 that has determined that the battery storage amount is equal to or greater than the predetermined storage amount ("Yes" in the drawing) controls the clutch control unit 52 to put the clutch 16 in the connected state. Output a command. Receiving this control command, the clutch control means 52 outputs a clutch connection command to the clutch 16, and puts the clutch 16 in a connected state ("clutch engagement" shown in FIG. 4) (step S16).

  When the clutch 16 is in the engaged state in step S <b> 16, the braking force control unit 48 outputs an information signal for controlling the braking force generated when the vehicle C is decelerated to the engine control unit 50. Upon receiving this information signal, the engine control means 50 controls the driving state of the engine 1. As a result, the driving state of the engine 1 is controlled to a driving state in which friction of the engine 1 that is the deceleration force of the vehicle C is generated ("deceleration force control by engine friction" shown in the figure) (step S24).

In step S24, after controlling the driving state of the engine 1, the motor control means 56 determines whether or not slip has occurred due to the locking of the drive wheels 2 based on the information signal output from the lock detecting means 54 (FIG. "Slip?" Shown in the figure) (step S26).
If the motor control means 56 determines in step S26 that no slip has occurred due to the lock of the drive wheels 2 ("No" shown in the figure), the processing performed by the braking force control device returns to the processing in step S10. (RETURN).

On the other hand, in step S26, the motor control means 56, which has determined that slip has occurred due to the lock of the drive wheel 2 ("Yes" shown in the figure), detects the rotational speeds of the drive wheel 2 and the driven wheel 6 (see FIG. ("Wheel speed reading" shown in the figure)) (step S28).
In step S28, the motor control means 56 that has detected the rotational speeds of the driving wheel 2 and the driven wheel 6 detects the rotational speed of the engine 1 ("engine rotational speed reading" shown in the drawing) (step S30).

When the rotational speed of the engine 1 is detected in step S30, the friction calculating means 58 calculates the friction of the engine 1 ("engine friction calculation" shown in the figure) based on the detected rotational speed (step S32).
In step S32, after calculating the friction of the engine 1, the inertia torque calculating means 60 calculates the inertia torques of the engine 1, the drive wheel 2 and the transmission 14 ("inner torque calculation" shown in the figure) ( Step S34).

In step S34, after calculating the inertia torque of the engine 1, the drive wheel 2 and the transmission 14, the rotational drive torque calculation means 62 calculates the torque generated by the rotational drive of the motor 4 ("motor torque calculation shown in the figure"). ”) (Step S36).
In step S36, after calculating the torque generated by the rotation drive of the motor 4, the half-clutch determination means 72 determines whether or not the clutch 16 is engaged while slipping ("clutch slip?" (Step S38).

  In step S38, when the half-clutch determination unit 72 determines that the clutch 16 is slipping and not connected ("No" shown in the figure), the gain switching unit 78 switches the feedback gain to the second gain. Thereby, the gain used for feedback control is set to the second gain that is smaller than the first gain (“set the motor feedback gain to be small” shown in the figure) (step S40). In step S40, after the gain switching unit 78 switches the feedback gain to the second gain, the process performed by the braking force control device shifts to the process in step S44.

  On the other hand, when the half clutch determining means 72 determines that the clutch 16 is engaged while slipping ("Yes" shown in the drawing) in step S38, the gain switching means 78 switches the feedback gain to the first gain. . Thus, the gain used for feedback control is set to the first gain that is larger than the second gain (“motor feedback gain set to large” shown in the figure) (step S42). In step S42, after the gain switching unit 78 switches the feedback gain to the first gain, the process performed by the braking force control device shifts to the process in step S44.

  In step S44, the motor torque control means 74 controls the torque generated by the rotational drive of the motor 4 so as to cancel the friction of the engine 1, and controls the torque generated by the motor 4 to the power running side. As a result, the driving wheel 2 is driven by the torque generated by the rotation drive of the motor 4 to suppress the locking of the driving wheel 2, and the slip generated by the locking of the driving wheel 2 ("motor slip control shown in the drawing" "Powering only") is suppressed.

Here, in step S44, the feedback gain switched in step S40 or step S42 is used to feedback-control the torque generated by the motor 4 by rotational driving.
In step S44, after the motor 4 controls the torque generated by the rotational drive, the deceleration determination means 66 determines whether or not the deceleration of the vehicle C during deceleration is equal to or greater than a predetermined deceleration (in the figure). ("Deceleration is not less than a predetermined value?") (Step S46).

  When the deceleration determination means 66 determines in step S46 that the deceleration of the vehicle C during deceleration is not equal to or greater than the predetermined deceleration ("No" shown in the figure), the processing performed by the braking force control device is as follows. The process proceeds to S48. Here, the determination that the deceleration of the vehicle C during deceleration is not greater than or equal to the predetermined deceleration is a determination that the deceleration of the vehicle C during deceleration is less than the predetermined deceleration.

In step S48, the rotational drive torque correction means 68 outputs an information signal including a command to weaken the torque generated by the rotational drive of the motor 4 at a predetermined rate to the motor torque control means 74. As a result, control is performed to weaken the torque generated by the rotational drive of the motor 4 at a predetermined rate ("motor power running weakening control" shown in the figure).
In step S48, after the control to weaken the torque generated by the rotational drive of the motor 4 at a predetermined rate is performed, the processing performed by the braking force control device returns to the processing in step S46.

  On the other hand, when the deceleration determination means 66 determines in step S46 that the deceleration of the vehicle C during deceleration is equal to or greater than a predetermined deceleration ("Yes" shown in the figure), the processing performed by the braking force control device is as follows. Return to the process of step S10 (RETURN). That is, in the processing of step S46 and step S48, the torque generated by the rotational drive of the motor 4 is corrected to decrease until the deceleration of the vehicle C during deceleration becomes equal to or greater than a predetermined deceleration.

(Operation)
Next, the operation of the vehicle including the braking force control device will be described with reference to FIGS. 1 to 4 and FIG.
FIG. 5 is a time chart showing the operation of the vehicle C provided with the braking force control device. In FIG. 5, the speed of the vehicle C in the forward state is indicated as “vehicle speed”, and the charged amount of the battery 26 is indicated as “charged amount”. The braking force required by the driver (required braking force) is indicated as “driver required braking force”, and the deviation between the rotational speed of the driving wheel 2 and the rotational speed of the driven wheel 6 is referred to as “front and rear wheel deviation”. The torque generated by the motor 4 and transmitted to the drive wheels 2 is indicated as “motor torque”. Further, the braking force generated by the friction of the engine 1 is indicated as “braking force by the engine friction”.

The time chart of FIG. 5 starts from a state in which when the vehicle C is traveling, a driver's deceleration request is generated, the amount of operation of the accelerator pedal 22 by the driver is “0”, and the required braking force is generated ( (See FIG. 1).
Note that the vehicle C having the braking force control device drives the engine 1 in a state where the amount of operation of the accelerator pedal 22 by the driver is small, that is, in a state where the driving force required by the driver (required driving force) is small. Instead, the vehicle travels only with the driving force generated by the motor 4. When the amount of operation of the accelerator pedal 22 by the driver increases and the required driving force reaches a certain level, the engine 1 is driven and travels with the driving force generated by the engine 1 (see FIG. 1).

When the required braking force is generated, the required braking force detection unit 44 calculates the required braking force and outputs an information signal including the calculation result to the braking force control unit 48 (see FIG. 2).
The braking force control means 48 that has received the input of the information signal output from the requested braking force detection means 44 further receives the input of the information signal output from the battery charge amount detection means 46, and is based on the requested braking force and the battery charge amount. The braking force generated when the vehicle C is decelerated is controlled (see FIG. 3).

  Here, as shown in FIG. 5, when the required braking force is generated, the battery storage amount is less than the predetermined storage amount. Therefore, the motor control unit 56 controls the operation of the motor 4 to regenerative braking. (See FIGS. 3 and 4). As a result, the motor 4 is regeneratively braked, the regenerative torque generated by the motor 4 is transmitted to the drive wheels 2 to obtain the braking force required when the vehicle C is decelerated, and the electric power generated by the regenerative braking of the motor 4 is The battery 26 is supplied via the inverter 24 (see FIG. 1). In the “motor torque” column, the torque of the motor 4 in a region where the torque of the motor 4 exceeds “0” with the position where the torque of the motor 4 is “0” as a boundary is indicated as “powering”. . Similarly, in the “motor torque” column, the torque of the motor 4 in the region where the torque of the motor 4 is less than “0” is indicated as “regeneration”.

  Further, as shown in FIG. 5, when the required braking force is generated and the battery storage amount is less than the predetermined storage amount, the clutch control means 52 outputs a clutch release command to the clutch 16, and the clutch 16 is controlled to a released state (see FIG. 2). As a result, the friction of the engine 1 is not transmitted to the drive wheels 2 regardless of the driving state of the engine 1, so that the braking force generated by the friction of the engine 1 is “0”.

As described above, when the motor 4 is regeneratively braked and the electric power generated by the regenerative braking of the motor 4 is supplied to the battery 26 via the inverter 24, as shown in the column “Storage amount”, To increase.
Here, for example, a case is considered where the transmission ratio of the transmission 14 is increased (shifted down) in order to increase the braking force. This downshifting is performed by a selection operation by the driver, or control with reference to the vehicle speed or the like.

  When the transmission gear ratio of the transmission 14 is increased by downshifting, at this point (“t0” in the figure), the torque generated by the motor 4 due to regenerative braking and transmitted to the drive wheels 2 increases to the regeneration side. The required braking force is reduced. In this state, for example, when the vehicle C is traveling on a low μ road, the braking force applied to the drive wheels 2 is increased by the regenerative torque generated by the motor 4, and the drive wheels 2 are locked ( Lock occurs). FIG. 5 shows a state in which the driving wheel 2 is locked by the braking force applied to the driving wheel 2 by the regenerative torque generated by the motor 4 that increases at the time t0.

  Lock generated in the drive wheel 2 is detected by the lock detecting means 54 that detects a state in which the rotational speed of the drive wheel 2 (front wheel) is less than the rotational speed of the driven wheel 6 (rear wheel) (FIGS. 2 and 4). reference). In the “front and rear wheel deviation” column, the front wheel rotational speed (the rotational speed of the driving wheel 2) is indicated by a broken line, and the rear wheel rotational speed (the rotational speed of the driven wheel 6) is indicated by a solid line. In the “front and rear wheel deviation” column, the portion where the front wheel rotational speed indicated by the broken line is not described is the portion where the rotational speed of the driving wheel 2 and the rotational speed of the driven wheel 6 are the same speed.

When the lock detection means 54 detects the occurrence of lock, the motor control means 56 outputs an information signal for controlling the operation of the motor 4 so as to suppress the lock of the drive wheels 2 to the inverter 24 (see FIGS. 2 and 4). ). As a result, the torque generated by the regenerative braking of the motor 4 and transmitted to the drive wheels 2 is increased to the power running side, thereby suppressing the lock of the drive wheels 2.
That is, when the required braking force is generated and the battery storage amount is less than the predetermined storage amount, the lock generated in the drive wheel 2 is generated by the torque generated by the regenerative braking of the motor 4 and transmitted to the drive wheel 2. Suppress (see FIGS. 2 and 4).

Torque generated by the regenerative braking and transmitted to the drive wheels 2 is increased to the power running side to suppress the lock of the drive wheels 2, and then the torque generated by the regenerative braking and transmitted to the drive wheels 2 by the motor 4 Is increased to the regeneration side in accordance with the increase in the gear ratio.
Here, for example, the gear ratio of the transmission 14 is prevented in order to prevent the driving wheel 2 from being locked, which is generated by increasing the torque generated by the regenerative braking and transmitted to the driving wheel 2 to the regeneration side. Consider the case of decreasing (shifting up). This shift up is performed by a selection operation by the driver, or control with reference to the vehicle speed or the like, similar to the shift down.

When the gear ratio of the transmission 14 is decreased by shifting up, at this time ("t1" in the figure), the torque generated by the motor 4 due to regenerative braking and transmitted to the drive wheels 2 increases to the power running side, The required braking force increases.
In addition, between the time t1 and the time t0, the torque generated by the regenerative braking of the motor 4 and transmitted to the drive wheels 2 is always on the regenerative side. Therefore, the electric power generated by the regenerative braking of the motor 4 is It is always supplied to the battery 26 via the inverter 24. Therefore, between the time point when the required braking force is generated and the time point t1, as shown in the “charge amount” column, the battery charge amount increases.

  When the electric power generated by the regenerative braking of the motor 4 is supplied to the battery 26 and the battery storage amount increases and exceeds the predetermined storage amount, at this point (“t2” in the figure), the clutch control means 52 A clutch connection command is output to the clutch 16 (see FIG. 2). As a result, the clutch 16 is controlled to be in the connected state, the friction of the engine 1 is transmitted to the drive wheels 2, and the braking force generated by the friction of the engine 1 is increased from “0”. Here, when controlling the clutch 16 to the connected state, the engine 1 may be driven or the engine 1 may be stopped. Further, when the clutch 16 is controlled to be in a connected state while the stopped engine 1 is being driven, the engine 1 is considered before the clutch 16 is controlled to be in a connected state in consideration of the responsiveness of the engine 1. Keep driving.

  Note that, between the time point t2 and the time point t1, the torque generated by the motor 4 due to regenerative braking and transmitted to the drive wheels 2 is always on the regenerative side, as between the time points t1 and t0. . For this reason, the electric power generated by the regenerative braking of the motor 4 is always supplied to the battery 26 via the inverter 24. Therefore, between the time point when the required braking force is generated and the time point t2, as shown in the “charge amount” column, the battery charge amount increases.

When the braking force generated by the friction of the engine 1 is increased from “0”, the torque generated by the regenerative braking of the motor 4 and transmitted to the drive wheels 2 increases with the increase to the power running side.
When the torque generated by the regenerative braking of the motor 4 and transmitted to the driving wheel 2 becomes “0”, the torque transmitted to the driving wheel 2 by the motor 4 at this time (“t3” in the figure) is The state of “0” is held. Accordingly, the increase in the braking force generated by the friction of the engine 1 is stopped, and the braking force generated by the friction of the engine 1 becomes constant.

  When the torque transmitted from the motor 4 to the drive wheel 2 is maintained in the “0” state, the torque generated by the motor 4 is not on the regeneration side, unlike the time t3. For this reason, the electric power generated by the regenerative braking of the motor 4 is always supplied to the battery 26 via the inverter 24 between the time t3 and the time t2. Therefore, between the time point when the required braking force is generated and the time point t3, as shown in the “charge amount” column, the battery charge amount increases. On the other hand, after the time t3, since the regenerative braking of the motor 4 is not performed, the power generation is not performed, and the battery storage amount does not increase. As shown in the figure, in the present embodiment, a case will be described in which the charged amount of battery is fully charged at time t3.

In this state, as in the case of t0 described above, for example, a case is considered in which the gear ratio of the transmission 14 is increased (shifted down) in order to increase the braking force.
When the transmission ratio of the transmission 14 is increased by downshifting in the above state, the braking force generated by the friction of the engine 1 increases at this point (“t4” in the figure), and the required braking force decreases. To do. In this state, for example, when the vehicle C is traveling on a low μ road, the braking force applied to the drive wheels 2 by the friction of the engine 1 increases, and the drive wheels 2 are locked (lock generation). To do. FIG. 5 shows a state in which the drive wheels 2 are locked by the braking force applied to the drive wheels 2 due to the friction of the engine 1 that increased at the time t4.

  Lock generated in the drive wheel 2 is detected by the lock detecting means 54 that detects a state in which the rotational speed of the drive wheel 2 (front wheel) is less than the rotational speed of the driven wheel 6 (rear wheel) (FIGS. 2 and 4). reference). When the lock detection means 54 detects the occurrence of lock, the motor control means 56 outputs an information signal for controlling the operation of the motor 4 so as to suppress the lock of the drive wheels 2 to the inverter 24 (see FIGS. 3 and 4). ). Thereby, the torque generated by the rotation drive of the motor 4 is transmitted to the drive wheels 2, and the lock of the drive wheels 2 is suppressed.

  At this time, the motor torque control means 74 calculates a torque generated by the rotational drive of the motor 4 so as to cancel the friction of the engine 1 calculated by the friction calculation means 58, and includes a control command for generating this torque. An information signal is generated. Then, the generated information signal is output to the inverter 24 (see FIGS. 3 and 4). As a result, the torque generated by the rotation of the motor 4 and transmitted to the drive wheels 2 is set to a torque equivalent to the friction of the engine 1, the braking force generated by the friction of the engine 1 is maintained, and the drive wheels 2 are locked. Suppress. In FIG. 5, the braking force generated by the friction of the engine 1 at the time of downshifting is indicated by a double arrow “EF”. Further, in FIG. 5, the torque generated by the motor 4 by rotational driving and transmitted to the drive wheels 2 is indicated by a double arrow “MT” so as to cancel the friction of the engine 1.

In other words, when the required braking force is generated and the battery storage amount is equal to or greater than the predetermined storage amount, the lock generated in the drive wheel 2 is generated by the torque generated by the motor 4 by rotational driving and transmitted to the drive wheel 2. Suppress (see FIGS. 2 and 4).
The torque generated by the motor 4 by rotational driving is used as the driving wheel 2 and the locking of the driving wheel 2 is suppressed, and then the torque generated by the motor 4 by rotational driving and transmitted to the driving wheel 2 is reduced. Then, the torque transmitted from the motor 4 to the drive wheels 2 is maintained in a “0” state, and the deceleration force of the vehicle C is obtained by the braking force generated by the friction of the engine 1.

  As described above, the vehicle braking force control method (braking force control method) implemented by the operation of the braking force control device of the present embodiment rotates the motor 4 when detecting the lock of the drive wheels 2. This is a method of driving the drive wheels 2. In addition to this, in the braking force control method of the present embodiment, the torque generated by the rotation drive of the motor 4 is set to be equal to or less than the friction of the engine 1. This is performed only when the vehicle 26 decelerates when the amount of electricity stored in the battery 26 is equal to or greater than the predetermined amount of electricity stored and braking force is generated by the friction of the engine 1.

(Effects of the first embodiment)
(1) In the braking force control apparatus according to the present embodiment, the lock detection means is connected to the driving wheel when the vehicle decelerates when the amount of charge of the battery is equal to or greater than the predetermined amount of charge and the braking force is generated due to engine friction. When the lock is detected, the motor control means controls the operation of the motor to be rotationally driven. In addition to this, the motor torque control means controls the torque generated by the rotational drive of the motor to be equal to or less than the friction calculated by the friction calculation means.

  For this reason, the drive wheel lock that occurs when the vehicle is decelerated only by engine braking due to engine friction is driven by rotating a motor that is more responsive to the command value than the engine, thereby improving responsiveness. It becomes possible to suppress. Further, it is possible to suppress the torque generated by the rotational drive of the motor in order to suppress the lock generated in the drive wheels from exceeding the braking force generated by the friction of the engine.

As a result, it is possible to prevent the battery from being overcharged, and to stabilize the behavior of the vehicle when the driving wheel is locked, thereby improving the steering stability of the vehicle.
Further, since it is possible to suppress the lock generated on the drive wheel while maintaining the braking force generated by the engine friction, the vehicle at the time of the drive wheel lock occurring while ensuring the deceleration of the vehicle. It becomes possible to stabilize the behavior.

(2) In the braking force control apparatus of the present embodiment, the motor torque control means controls the torque generated by the rotational drive of the motor to be the torque that is calculated by the friction calculation means and cancels out the engine friction.
For this reason, the torque generated by the rotational drive of the motor in order to suppress the lock generated on the drive wheels in the state where the braking force generated by the engine friction is generated is the maximum in the state where the deceleration of the vehicle is ensured. It is possible to increase it as much as possible.
As a result, the lock generated on the drive wheel can be efficiently suppressed.

(3) In the braking force control apparatus of the present embodiment, the rotational drive torque calculation means calculates the torque generated by the rotational drive of the motor. This calculation is performed based on the engine friction calculated by the friction calculation means and the inertia torque of the engine, drive wheels and transmission calculated by the inertia torque calculation means.
For this reason, in order to suppress the lock generated in the drive wheels, the torque generated by the rotational drive of the motor can be controlled according to the inertia torque of the engine, the drive wheels and the transmission in addition to the friction of the engine It becomes.
As a result, it is possible to control the torque generated by the rotational drive of the motor in consideration of the vehicle's inertia torque during deceleration in addition to the engine friction, so that the lock generated on the drive wheels can be accurately controlled. It becomes possible to do.

(4) In the braking force control device of the present embodiment, the deceleration detection means detects the vehicle deceleration in a state where the motor torque control means controls the torque generated by the rotational drive, and the deceleration determination means It is determined whether or not the deceleration detected by the deceleration detection means is less than a predetermined deceleration. When the deceleration determination means determines that the vehicle deceleration is less than the predetermined deceleration, the motor torque control means controls the rotation drive torque correction means until the vehicle deceleration exceeds a predetermined deceleration. Correct the reduced torque.

For this reason, it is possible to suppress the state in which the vehicle deceleration is less than the predetermined deceleration, that is, the vehicle traveling state from changing from deceleration to powering or acceleration, and to suppress the lock generated on the drive wheels. It becomes.
As a result, it is possible to suppress the lock generated on the drive wheels without giving the driver a sense of discomfort with respect to the driver's request for braking force when the vehicle is decelerating.

(5) In the braking force control apparatus of the present embodiment, when the half-clutch determination means determines that the clutch is engaged while slipping, the feedback gain used for feedback control of the torque generated by the rotation drive of the motor is Switch to one gain. On the other hand, if it is determined that the clutch is connected without slipping, the feedback gain used for feedback control is switched to a second gain smaller than the first gain.

For this reason, in a state where the clutch is connected while slipping, it is possible to ensure the responsiveness of the motor to the command value, and it is possible to suppress the occurrence of hunting due to the torque fluctuation of the motor.
Here, generation of hunting caused by torque fluctuation of the motor and suppression of the generated hunting will be described.
When obtaining vehicle deceleration due to engine friction, when the clutch is engaged while slipping, the road surface μ has an effect on the vehicle behavior compared to when the clutch is engaged without slipping. growing. In such a case, if the feedback gain is large, the torque fluctuation of the motor becomes large, which may cause hunting.

On the other hand, in the braking force control apparatus of the present embodiment, the feedback gain is made smaller in the state where the clutch is connected without slipping than in the state where the clutch is connected while slipping. For this reason, it is possible to ensure the responsiveness of the motor to the command value in a state where the clutch is connected without slipping, and it is possible to suppress the torque fluctuation of the motor.
As a result, it is possible to stably suppress the lock generated on the drive wheel regardless of the state of the clutch.

(6) In the braking force control apparatus according to the present embodiment, the clutch control means does not output the clutch connection command and the clutch release command during the feedback control of the torque generated by the rotation drive of the motor.
For this reason, it is possible to suppress a change in braking force and occurrence of lock of the drive wheels by controlling the clutch in the connected state to the released state during feedback control. Similarly, it is possible to suppress a change in braking force and occurrence of lock on the drive wheels by controlling the released clutch to the engaged state during feedback control.
As a result, it becomes possible to stabilize the behavior of the vehicle at the time of deceleration, and to stably suppress the lock generated on the drive wheels.

(7) In the braking force control method according to the present embodiment, when the charged amount of the battery is equal to or greater than the predetermined charged amount and the braking force is generated by engine friction and the vehicle is decelerated, the motor is turned on. The drive wheel is driven by rotating it. In addition to this, the torque generated by the rotational drive of the motor is set to be equal to or less than the engine friction.
For this reason, the drive wheel lock that occurs when the vehicle is decelerated only by engine braking due to engine friction is driven by rotating a motor that is more responsive to the command value than the engine, thereby improving responsiveness. It becomes possible to suppress. Further, it is possible to suppress the torque generated by the rotational drive of the motor in order to suppress the lock generated in the drive wheels from exceeding the braking force generated by the friction of the engine.

As a result, it is possible to prevent the battery from being overcharged, and to stabilize the behavior of the vehicle when the driving wheel is locked, thereby improving the steering stability of the vehicle.
Further, since it is possible to suppress the lock generated on the drive wheel while maintaining the braking force generated by the engine friction, the vehicle at the time of the drive wheel lock occurring while ensuring the deceleration of the vehicle. It becomes possible to stabilize the behavior.

(Application examples)
(1) In the braking force control apparatus according to the present embodiment, the motor torque control unit controls the torque generated by the rotational drive of the motor to be the torque that cancels the friction calculated by the friction calculation unit. It is not limited. That is, the motor torque control means may control the torque generated by the rotational drive of the motor to be less than the friction calculated by the friction calculation means. In short, the motor torque control means may control the torque generated by the rotation drive of the motor to be equal to or less than the friction calculated by the friction calculation means.

(2) In the braking force control apparatus of the present embodiment, the rotational drive torque calculation means calculates the torque generated by the rotational drive of the motor based on the friction of the engine and the inertia torque of the engine, drive wheels and transmission. . However, the present invention is not limited to this. That is, for example, the configuration of the motor control unit may not include the rotational drive torque calculation unit, the friction calculation unit, and the inertia torque calculation unit. The motor torque control means may control the torque generated by the rotational drive of the motor regardless of the friction of the engine, the inertia torque of the engine, the drive wheels, and the transmission.

(3) In the braking force control apparatus of the present embodiment, the rotational drive torque correction means corrects the torque controlled by the motor torque control means until the vehicle deceleration is equal to or greater than a predetermined deceleration. This reduction correction is performed only when the deceleration determination unit determines that the vehicle deceleration detected by the deceleration detection unit is less than a predetermined deceleration. However, the configuration of the braking force control device and the processing performed by the braking force control device are not limited to this. That is, for example, the configuration of the motor control unit may be a configuration that does not include the deceleration detection unit, the deceleration determination unit, and the rotational drive torque correction unit. And it is good also as a structure which does not perform the reduction | decrease correction with respect to the torque which the motor torque control means controlled.

(4) In the braking force control apparatus of the present embodiment, the feedback gain used for feedback control is switched to the first gain or the second gain according to the determination result of the half-clutch determination means. However, the present invention is not limited to this. That is, for example, the configuration of the motor control unit may be a configuration that does not include the half-clutch determination unit, and the configuration of the motor torque control unit may not include the gain switching unit.

(5) In the braking force control apparatus of the present embodiment, the clutch control means is configured not to output the clutch connection command and the clutch release command during the feedback control, but is not limited thereto. That is, the clutch control means outputs the clutch connection command and the clutch release command based on the determination as to whether or not the charged amount of the battery is greater than or equal to the charged amount regardless of whether feedback control is being performed. It is good also as a structure to perform.

Hereinafter, the braking force control apparatus to which the above application examples (1) to (5) are applied will be described with reference to FIG.
Note that the configuration of the braking force control apparatus to which the application examples (1) to (5) are applied is not particularly illustrated, but the points different from the first embodiment described above are the motor control means, the motor torque control means, and the clutch control. It is the structure of a means. Specifically, the configuration of the motor control means includes a rotation drive torque calculation means, a friction calculation means, an inertia torque calculation means, a deceleration detection means, a deceleration determination means, a rotation drive torque correction means, and a half clutch determination means. It has no configuration. Further, the configuration of the motor torque control means is not provided with the gain switching means. Further, the clutch control means is configured to output a clutch connection command and a clutch release command regardless of whether feedback control is being performed.

FIG. 6 is a flowchart showing processing of the braking force control apparatus in the application example of the first embodiment.
The processing performed by the braking force control apparatus in the flowchart shown in FIG. 6 is the same as the flowchart shown in FIG. 4 described above with respect to the processing from the start (START) from the state in which the vehicle C is running to step S26. It is the same. For this reason, the description of the processing from the above START to step S26 is omitted.
If the motor control means 56 determines in step S26 that no slip has occurred due to the lock of the drive wheels 2 ("No" shown in the figure), the processing performed by the braking force control device returns to the processing in step S10. (RETURN).

  On the other hand, in step S26, the motor control means 56, which has determined that slip has occurred due to the lock of the drive wheels 2 ("Yes" shown in the figure), controls the operation of the motor 4 to rotational drive. As a result, the driving wheel 2 is driven by the torque generated by the rotation drive of the motor 4 to suppress the locking of the driving wheel 2, and the slip generated by the locking of the driving wheel 2 ("motor slip control shown in the drawing" "Powering only") is suppressed (step S50).

When the operation of the motor 4 is controlled to rotate in step S50, the process performed by the braking force control device returns to the process of step S10 (RETURN).
Therefore, in the braking force control device to which the application examples (1) to (6) are applied, the lock of the driving wheel 2 is suppressed by a simple configuration and processing as compared with the braking force control device of the first embodiment described above. Will be.

  In the braking force control device to which the application examples (1) to (6) are applied, the configuration of the motor control unit and the motor torque control unit is compared with the braking force control device of the first embodiment described above. However, the present invention is not limited to this. That is, the configuration of the motor control means and the motor torque control means is the same as that of the braking force control device of the first embodiment described above. And according to conditions, such as a state of a vehicle and a driving state, you may reduce the component requirement to be used compared with 1st embodiment.

DESCRIPTION OF SYMBOLS 1 Engine 2 Drive wheel 4 Motor 6 Driven wheel 10 Vehicle controller 14 Transmission 16 Clutch 18 Front wheel speed sensor 24 Inverter 26 Battery 36 Engine side disk rotational speed sensor 38 Transmission side disk rotational speed sensor 40 Rear wheel speed sensor 44 Required braking force detection means 46 Battery charged amount detection means 48 Braking force control means 50 Engine control means 52 Clutch control means 54 Lock detection means 56 Motor control means 58 Friction calculation means 60 Inertia torque calculation means 62 Rotation drive torque calculation means 64 Deceleration Detection means 66 Deceleration determination means 68 Rotation drive torque correction means 70 Rotational deviation detection means 72 Half clutch determination means 74 Motor torque control means 76 Feedback control means 78 Gain switching means C Vehicle

Claims (7)

An engine capable of driving the drive wheels, and a motor capable of driving the drive wheels by rotational drive and storing the battery by regenerative braking,
A braking force control device for a vehicle provided in a vehicle that generates braking force by friction of the engine at the time of deceleration when the storage amount of the battery is equal to or greater than a predetermined storage amount,
Lock detection means for detecting the lock of the drive wheel, motor control means for controlling the operation of the motor, friction calculation means for calculating the friction, and motor torque control for controlling the torque generated by the rotational drive of the motor Means, and
The motor control means controls the operation of the motor by the electric power supplied from the battery when the lock detection means detects the lock of the drive wheel during deceleration when the charged amount of the battery is greater than or equal to a predetermined charged amount. Control to rotational drive,
The motor torque control means controls the braking force control apparatus for a vehicle so as to control the torque generated by the rotation of the motor to be equal to or less than the friction calculated by the friction calculation means.   2. The vehicle control according to claim 1, wherein the motor torque control unit controls the torque generated by the rotation drive of the motor so as to cancel the friction calculated by the friction calculation unit. 3. Power control device. The vehicle has a transmission interposed in a driving force transmission path between the engine and the motor and the driving wheel,
Inertia torque calculation means for calculating inertia torques of the engine, the drive wheels and the transmission, respectively, and rotational drive torque calculation means for calculating torque generated by rotational drive of the motor,
2. The rotational drive torque calculation means calculates a torque generated by the rotational drive of the motor based on the friction calculated by the friction calculation means and the inertia torque calculated by the inertia torque calculation means. Or the braking force control device for a vehicle according to 2; A deceleration detecting means for detecting deceleration of the vehicle in a state in which the torque generated by the rotational drive is controlled by the motor torque control means, and the deceleration detected by the deceleration detecting means is less than a predetermined deceleration. Deceleration determining means for determining whether or not, and rotational drive torque correcting means for correcting the torque controlled by the motor torque control means,
When the deceleration determination unit determines that the deceleration of the vehicle is less than the predetermined deceleration, the rotational drive torque correction unit increases the motor until the deceleration of the vehicle becomes equal to or greater than the predetermined deceleration. 4. The vehicle braking force control device according to claim 1, wherein the torque controlled by the torque control unit is corrected to decrease. 5. The vehicle includes a driven wheel disposed offset from the driving wheel in the vehicle front-rear direction, and a clutch that connects or releases a driving force transmission path between the engine and the driving wheel.
A rotation deviation detection means for detecting a deviation between the rotation state of the driving wheel and the rotation state of the driven wheel; and a half-clutch determination means for determining whether or not the clutch is connected while slipping.
The motor torque control means includes feedback control means for feedback-controlling torque generated by the rotational drive of the motor based on the deviation detected by the rotation deviation detection means, and based on the determination result of the half-clutch determination means. Gain switching means for switching the feedback gain used for feedback control in two ways,
The feedback control means performs the feedback control when the deviation detected by the rotation deviation detection means is equal to or greater than a predetermined deviation;
The gain switching means switches the feedback gain to the first gain when the half clutch determining means determines that the clutch is connected while slipping, and the half clutch determining means allows the clutch not to slip. 5. The vehicle braking force control device according to claim 1, wherein when it is determined that the connection is established, the feedback gain is switched to a second gain smaller than the first gain. 6. If the battery charge amount is greater than or equal to a predetermined charge amount, a clutch connection command for connecting the clutch is output, and if the battery charge amount is less than the predetermined charge amount, the clutch is released. Clutch control means for outputting a clutch release command;
6. The vehicle braking force control apparatus according to claim 5, wherein the clutch control means does not output the clutch engagement command and the clutch release command during the feedback control. A braking force control method for a vehicle that generates a braking force by friction of an engine capable of driving a drive wheel at the time of deceleration when the storage amount of a battery stored by regenerative braking of a motor is a predetermined storage amount or more,
When detecting the lock of the drive wheel during deceleration when the charged amount of the battery is equal to or greater than a predetermined charged amount, the motor is driven to rotate by the electric power supplied from the battery , and the drive wheel is driven, and A method for controlling a braking force of a vehicle, wherein a torque generated by rotational driving of the motor is equal to or less than the friction.

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