JP6747902B2 - Braking device and braking system - Google Patents

Description

The present invention relates to a brake device and a brake system that apply a braking force to a vehicle such as an automobile.

BACKGROUND ART As a brake device provided in a vehicle, a vehicle brake device that operates based on driving of an electric motor (electric motor) is known (Patent Document 1). Here, Patent Document 1 describes a technique in which after the vehicle is stopped by automatic braking, the hydraulic pressure of the hydraulic brakes of the front wheels is released and the parking lock mechanism of the electric brakes of the rear wheels is activated.

JP, 2007-15553, A

According to the related art, for example, when the driver tries to start again immediately after the vehicle is stopped by the automatic brake, the parking lock mechanism may be activated to hinder the smooth start of the vehicle.

An object of the present invention is to provide a brake device and a brake system that actuate a parking lock mechanism so as to comply with a driver's intention.

In order to solve the above-mentioned problems, a braking device according to the present invention is an electric motor that propels a piston that presses a braking member against a member to be braked, and a braking force control that controls the hydraulic pressure supply to the piston to control the braking force. An electric motor control device that is connected to the device and that controls the drive of the electric motor in response to a braking holding request from the braking force control device, wherein the electric motor control device controls the driver after the vehicle is stopped. If the start intention is detected, when the brake force control apparatus or al dynamic braking holding request is outputted, prohibiting the holding of the braking force.

Further, the braking system according to the present invention includes an electric motor that propels a piston that presses a braking member against a member to be braked, an electric motor control device that controls driving of the electric motor, and a hydraulic pressure supply to the piston to control a braking force. And a braking force control device for controlling the electric motor control device, wherein the electric motor control device receives the braking holding request from the braking force control device and drives the electric motor to bring the electric motor into the braking holding state when the vehicle is stopped. The electric motor control device does not drive the electric motor in response to the output of the braking holding request from the braking force control device when the driver's intention to start after the vehicle is stopped is detected.

INDUSTRIAL APPLICABILITY The braking device and the braking system of the present invention inhibit the operation of the parking lock mechanism by detecting the intention to start the driving vehicle, so that the vehicle can be started smoothly, and the parking lock mechanism operates in accordance with the driver's intention. It will be possible.

1 is a conceptual diagram of a vehicle equipped with a brake system according to an embodiment. The longitudinal cross-sectional view which expands and shows the disc brake with an electric parking brake function provided in the rear wheel side in FIG. The block diagram which shows the parking brake control apparatus in FIG. The flow chart which shows the control processing of a parking brake control device. FIG. 5 is a characteristic diagram showing an example of changes over time in vehicle speed, accelerator pedal operation, apply request, and parking brake operation.

Hereinafter, the case where the brake device and the brake system according to the embodiment are mounted on a four-wheeled vehicle will be described as an example with reference to the accompanying drawings. Note that each step of the flowchart shown in FIG. 4 uses the notation “S” (for example, step 1=“S1”).

In FIG. 1, on the lower side (road surface side) of the vehicle body 1 that constitutes the body of the vehicle, there are a total of four front and rear wheels 2 (FL, FR) and left and right rear wheels 3 (RL, RR). Wheels are provided. The wheels (each front wheel 2, each rear wheel 3) form a vehicle together with the vehicle body 1. The vehicle is equipped with a brake system for applying a braking force. Hereinafter, the vehicle brake system will be described.

The front wheel 2 and the rear wheel 3 are provided with a disk rotor 4 as a braked member (rotating member) that rotates together with each wheel (each front wheel 2, each rear wheel 3). A braking force is applied to the disk rotor 4 for the front wheels 2 by a front wheel side disk brake 5 which is a hydraulic disk brake. A braking force is applied to the disc rotor 4 for the rear wheel 3 by a rear disc brake 6 which is a hydraulic disc brake having an electric parking brake function.

A pair (one set) of rear wheel side disc brakes 6 provided corresponding to the left and right rear wheels 3 constitutes a brake device (electric parking brake device) together with a parking brake control device 26 described later. Further, the rear wheel side disc brake 6 constitutes a brake system together with the parking brake control device 26 and an ESC control device 17 described later. As shown in FIG. 2, the rear wheel side disc brake 6 includes, for example, a mounting member 6A called a carrier, a caliper 6B as a wheel cylinder, and a pair of brake pads 6C as a braking member (friction member, friction pad). , And a piston 6D as a pressing member.

The mounting member 6A is fixed to a non-rotating portion of the vehicle and is formed so as to straddle the outer peripheral side of the disc rotor 4. The caliper 6B is provided on the mounting member 6A so as to be movable in the axial direction of the disc rotor 4. The brake pad 6C is movably attached to the attachment member 6A, and is arranged so as to be able to contact the disc rotor 4. The piston 6D presses the brake pad 6C against the disc rotor 4.

In this case, the caliper 6B propels the brake pad 6C with the piston 6D by supplying (adding) hydraulic pressure (brake hydraulic pressure) into the cylinder 6B1 based on the operation of the brake pedal 9 or the like. At this time, the brake pad 6C is pressed against both surfaces of the disc rotor 4 by the claw portion 6B2 of the caliper 6B and the piston 6D. As a result, braking force is applied to the rear wheel 3 that rotates with the disc rotor 4.

Further, the rear wheel side disc brake 6 is provided with an electric actuator 7 and a pressing member holding mechanism 8. The electric actuator 7 is configured to include an electric motor 7A as an electric motor, a reduction mechanism (not shown) for reducing the rotation of the electric motor 7A, and the like. The electric motor 7A serves as a drive source for propelling the piston 6D. The pressing member holding mechanism 8 is a holding mechanism that holds the pressing force of the brake pad 6C. That is, the pressing member holding mechanism 8 converts the rotation of the electric motor 7A into the axial displacement of the piston 6D, and holds the piston 6D propelled by the electric motor 7A. The pressing member holding mechanism 8 is configured as a rotation/linear motion converting mechanism such as a spindle nut mechanism.

The rear wheel side disc brake 6 extends the wheel (rear wheel 3) by propelling the piston 6D by the brake fluid pressure generated based on the operation of the brake pedal 9 and pressing the disc rotor 4 with the brake pad 6C. Applies braking force to the vehicle. In addition to this, the rear wheel side disc brake 6 propels the piston 6D via the pressing member holding mechanism 8 by the electric motor 7A in response to an operation request based on a signal from the parking brake switch 25, as described later. Then, the braking force (parking brake or auxiliary brake) is applied to the vehicle.

That is, the rear wheel side disc brake 6 as the parking brake device drives the piston 6D with the electric motor 7A in response to the parking brake request signal (Apply request signal) which is an apply request for applying the parking brake. It is possible to maintain braking. Along with this, the rear wheel side disc brake 6 can brake the vehicle by hydraulic pressure supply from a hydraulic pressure source (a master cylinder 12, which will be described later, and a hydraulic pressure supply device 15 if necessary) in response to the operation of the brake pedal 9. Has become.

In this way, the rear wheel side disc brake 6 has the pressing member holding mechanism 8 that presses the brake pad 6C against the disc rotor 4 by the electric motor 7A and holds the pressing force of the brake pad 6C, and also the electric motor 7A. The brake pad 6C can be pressed against the disc rotor 4 by the hydraulic pressure added separately from the pressing by the.

On the other hand, a pair (one set) of front wheel side disc brakes 5 provided corresponding to the left and right front wheels 2 have substantially the same configuration as the rear wheel side disc brakes 6 except for the mechanism related to the operation of the parking brake. Has been done. That is, as shown in FIG. 1, the front wheel side disc brake 5 includes a mounting member (not shown), a caliper 5A, a brake pad (not shown), a piston 5B, etc., but the parking brake is activated and released. The electric actuator 7 (electric motor 7A) and the pressing member holding mechanism 8 for performing the above are not provided. However, the front wheel-side disc brake 5 drives the piston 5B by hydraulic pressure generated based on the operation of the brake pedal 9 or the like, and applies braking force to the wheels (front wheels 2) and thus to the vehicle. It is similar to the disc brake 6.

The front wheel side disc brake 5 may be a disc brake with an electric parking brake function, like the rear wheel side disc brake 6. Further, in the embodiment, the hydraulic disc brake 6 having the electric motor 7A is used as the parking brake device. However, the parking brake device is not limited to this, and for example, a disc brake having an electric drum type parking brake, a cable puller type parking brake device that applies a parking brake by pulling a cable with an electric motor, or the like is used. May be. That is, the parking brake device presses (promotes) the friction member (pad, shoe) against the rotating member (rotor, drum) based on the drive of the electric motor (electric actuator), and holds and releases the pressing force. Various electric parking brake mechanisms can be used as long as they can perform the above.

A brake pedal 9 is provided on the front board side of the vehicle body 1. The brake pedal 9 is depressed by the driver when the vehicle is braked. Based on this operation, the disc brakes 5 and 6 apply and release the braking force as the service brakes. The brake pedal 9 is provided with a brake operation detection sensor (brake sensor) 10 such as a brake lamp switch, a pedal switch, and a pedal stroke sensor.

The brake operation detection sensor 10 detects whether or not the brake pedal 9 is stepped on, or detects the operation amount, and outputs a detection signal to the ESC control device 17. The detection signal of the brake operation detection sensor 10 is transmitted, for example, via the vehicle data bus 20 or a communication line (not shown) that connects the ESC control device 17 and the parking brake control device 26 (parking brake control). Output to device 26).

The depression operation of the brake pedal 9 is transmitted to the master cylinder 12 functioning as a hydraulic pressure source via the booster 11. The booster 11 is configured as a negative pressure booster (atmospheric pressure booster) or an electric booster (electric booster) provided between the brake pedal 9 and the master cylinder 12, and provides a pedal effort when the brake pedal 9 is depressed. Is transmitted to the master cylinder 12.

At this time, the master cylinder 12 generates hydraulic pressure by the brake fluid supplied (supplemented) from the master reservoir 13. The master reservoir 13 is composed of a hydraulic fluid tank containing a brake fluid. The mechanism for generating the hydraulic pressure by the brake pedal 9 is not limited to the above configuration, and may be a mechanism for generating the hydraulic pressure according to the operation of the brake pedal 9, for example, a brake-by-wire system mechanism or the like. ..

The hydraulic pressure generated in the master cylinder 12 is sent to a hydraulic pressure supply device 15 (hereinafter referred to as ESC 15) via, for example, a pair of cylinder side hydraulic pressure pipes 14A and 14B. The ESC 15 is arranged between the disc brakes 5 and 6 and the master cylinder 12, and distributes the hydraulic pressure from the master cylinder 12 to the disc brakes 5 and 6 via the brake side piping portions 16A, 16B, 16C and 16D. To do. As a result, the braking force is applied to each of the wheels (each front wheel 2, each rear wheel 3) independently of each other. In this case, the ESC 15 can supply the hydraulic pressure to each of the disc brakes 5 and 6, that is, increase the hydraulic pressure of each of the disc brakes 5 and 6, even in a mode that does not follow the operation amount of the brake pedal 9.

For this purpose, the ESC 15 has a dedicated control device constituted by, for example, a microcomputer, that is, an ESC control device 17 also called a control unit for a hydraulic pressure supply device. The ESC control device 17 performs drive control such as opening and closing each control valve (not shown) of the ESC 15 and rotating and stopping an electric motor (not shown) for the hydraulic pump. As a result, the ESC control device 17 performs control to increase, decrease, or maintain the brake fluid pressure supplied from the brake side piping portions 16A to 16D to the disc brakes 5 and 6. As a result, various brake controls such as boost control, braking force distribution control, brake assist control, antilock brake control (ABS), traction control, vehicle stabilization control (including skid prevention), slope start assist control, Automatic stop control, automatic operation control, etc. are executed.

As described above, the ESC control device 17 is a braking force control device that controls the hydraulic pressure supply to the pistons 5B and 6D of the disc brakes 5 and 6 to control the braking force. The ESC control device 17 is supplied with electric power from a battery 18 (or a generator driven by an engine), which serves as a vehicle power supply, through a power supply line 19. As shown in FIG. 1, the ESC control device 17 is connected to the vehicle data bus 20. A known ABS unit may be used instead of the ESC 15. Further, without providing the ESC 15 (that is, omitted), the master cylinder 12 and the brake side piping portions 16A to 16D can be directly connected.

The vehicle data bus 20 constitutes a CAN (Controller Area Network) as a serial communication unit mounted on the vehicle body 1. A large number of electronic devices (for example, various ECUs) mounted on the vehicle, the ESC control device 17, the parking brake control device 26, and the like perform multiplex communication in the vehicle among them by the vehicle data bus 20. In this case, as the vehicle information sent to the vehicle data bus 20, for example, the brake operation detection sensor 10, the M/C pressure sensor 21 that detects the master cylinder hydraulic pressure, and the W/C pressure sensor 22 that detects the wheel cylinder hydraulic pressure. The information (vehicle information) based on the detection signal (output signal) from the.

Further, as the vehicle information sent to the vehicle data bus 20, for example, an ignition switch, a seat belt sensor, a door lock sensor, a door opening sensor, a seating sensor, a vehicle speed sensor, a steering angle sensor, an accelerator sensor (accelerator operation sensor), a throttle. Sensor, engine rotation sensor, stereo camera, millimeter wave radar, gradient sensor (tilt sensor), shift sensor (transmission data), acceleration sensor (G sensor), wheel speed sensor, pitch sensor for detecting movement of the vehicle in the pitch direction, etc. Information (vehicle information) based on the detection signal (output signal) from is also included.

In addition to the ESC control device 17 and the parking brake control device 26, an automatic brake control device 23 is connected to the vehicle data bus 20. The automatic brake control device 23 is an automatic brake control unit that outputs an automatic brake command (automatic brake braking command value). The automatic brake control device 23 is also configured to include a microcomputer like the ESC control device 17 and the parking brake control device 26, and is connected to the ESC control device 17, the parking brake control device 26 and the like via the vehicle data bus 20. There is.

Here, the automatic brake control device 23 is connected to, for example, the outside world recognition sensor 24. The external environment recognition sensor 24 constitutes an object position measuring device that measures the position of an object around the vehicle, and is, for example, a camera such as a stereo camera or a single camera (for example, a digital camera), and/or a laser radar or an infrared ray. A radar such as a radar or a millimeter wave radar (for example, a light emitting element such as a semiconductor laser and a light receiving element that receives the light emitting element) can be used. The external environment recognition sensor 24 is not limited to a camera or a radar, and various sensors (detection device, measurement device, radio wave detector) that can recognize (detect) the state of the external environment around the vehicle can be used.

The automatic brake control device 23 calculates, for example, a distance to an object in front (for example, another vehicle or an obstacle) based on the detection result (information) of the external environment recognition sensor 24, and the distance and the current vehicle. The automatic braking command value corresponding to the braking force (braking hydraulic pressure) to be applied is calculated based on the traveling speed and the like. The calculated automatic brake braking command value is output from the automatic brake control device 23 to the vehicle data bus 20 as an automatic brake command.

In this case, for example, when the ESC control device 17 acquires the automatic brake command via the vehicle data bus 20, based on the acquired automatic brake command, opening/closing of the control valve of the ESC 15 and the electric motor for the hydraulic pump. Drive. That is, the ESC 15 applies a braking force (automatic brake) to the wheels (each front wheel 2, each rear wheel 3) by increasing the brake fluid pressure supplied to the disc brakes 5, 6 based on the automatic brake command. To do.

At this time, when the vehicle stops, the ESC control device 17 outputs an apply request (apply command) to the parking brake control device 26 as needed. That is, the ESC control device 17 outputs an apply request to the parking brake control device 26 before releasing (reducing) the brake fluid pressure by the ESC 15. For example, after the vehicle is stopped by the automatic brake, the ESC control device 17 reduces the load on the ESC 15 (load of hydraulic pump, load of electric motor, load of control valve, etc.) from braking by hydraulic pressure to electric parking. When switching to braking by the brake, an apply request is output to the parking brake control device 26. Further, the ESC control device 17, for example, in order to switch from hydraulic braking to braking of the electric parking brake when the driver's intention to park (release of seat belt or opening of door on driver's side) is detected. It is also possible to output an apply request to the parking brake control device 26. The parking brake control device 26 applies the braking force by the parking brake even after the brake fluid pressure is released by the ESC 15 by driving the electric motor 7A to the apply side based on the apply request from the ESC control device 17. can do.

A parking brake switch (PKB-SW) 25 as an operation switch is provided in the vehicle body 1 at a position near a driver's seat (not shown). The parking brake switch 25 serves as an operation instruction unit operated by the driver. The parking brake switch 25 sends a signal (operation request signal) corresponding to a parking brake operation request (an apply request, which is a holding request, a release request, which is a release request), which corresponds to a driver's operation instruction, to the parking brake control device 26. Communicate to. That is, the parking brake switch 25 is an operation request signal (holding request) for performing an apply operation (holding operation) or a release operation (release operation) of the piston 6D and then the brake pad 6C based on the drive (rotation) of the electric motor 7A. An Apply request signal which is a signal and a release request signal which is a release request signal) are output to the parking brake control device 26 which is a parking brake control unit (controller).

When the driver operates the parking brake switch 25 to the braking side (apply side), that is, when there is an apply request (braking holding request) for applying the braking force to the vehicle, the parking brake switch 25 applies the apply force. A request signal (parking brake request signal) is output. In this case, electric power for rotating the electric motor 7A to the braking side is supplied to the electric motor 7A of the rear wheel side disc brake 6 via the parking brake control device 26. At this time, the pressing member holding mechanism 8 propels (presses) the piston 6D toward the disk rotor 4 based on the rotation of the electric motor 7A, and holds the propelled piston 6D. As a result, the rear wheel side disc brake 6 is brought into a state in which a braking force as a parking brake (or an auxiliary brake) is applied, that is, in an apply state (braking holding state).

On the other hand, when the driver operates the parking brake switch 25 to the braking release side (release side), that is, when there is a release request for releasing the braking force of the vehicle (braking release request), the parking brake switch is released. A release request signal is output from 25. In this case, electric power for rotating the electric motor 7A in the direction opposite to the braking side is supplied to the electric motor 7A of the rear wheel side disc brake 6 via the parking brake control device 26. At this time, the pressing member holding mechanism 8 releases the holding of the piston 6D by the rotation of the electric motor 7A (releases the pressing force of the piston 6D). As a result, the rear wheel side disc brake 6 is in a state where the application of the braking force as the parking brake (or the auxiliary brake) is released, that is, in the released state (braking release state).

The parking brake stops the engine when, for example, the vehicle stops for a predetermined time (for example, it is determined to stop when the speed detected by the vehicle speed sensor is less than 4 km/h for a predetermined time due to deceleration during traveling). When the shift lever is operated to P, the door is opened, the seat belt is released, and the like, based on the automatic apply request by the apply determination logic of the parking brake in the parking brake control device 26, It can be configured to be automatically applied (auto apply). Further, the parking brake is, for example, when the vehicle is running (for example, when the speed detected by the vehicle speed sensor is 5 km/h or more for a predetermined period of time, the vehicle is judged to be running as the speed increases after the vehicle is stopped). Based on the automatic release request by the parking brake release determination logic in the parking brake control device 26, such as when operated, when the clutch pedal is operated, when the shift lever is operated other than P and N, and the like. It can be configured to be automatically released (auto release). Auto apply and auto release can be configured as a switch failure auxiliary function that automatically applies or releases the braking force when the parking brake switch 25 fails.

Furthermore, when there is an apply request by the parking brake switch 25 during traveling of the vehicle, more specifically, a request for a dynamic parking brake (dynamic apply) such as urgently using the parking brake as an auxiliary brake during traveling. Even if there is, the parking brake control device 26 applies and releases the braking force according to the operation of the parking brake switch 25. For example, the parking brake control device 26 applies the braking force while the parking brake switch 25 is operated to the braking side (while the operation to the braking side is continued), and the braking force is applied when the operation is completed. To cancel. At this time, the parking brake control device 26 automatically applies and releases the braking force (ABS control) depending on the state of the wheels (rear wheels 3), that is, whether or not the wheels are locked (slip). It can be configured to perform.

The parking brake control device 26 as an electric motor control device constitutes a brake device (parking brake device) together with the electric motors 7A, 7A of the rear wheel side disc brakes 6, 6. Further, the parking brake control device 26 constitutes a brake system together with the electric motors 7A, 7A of the rear wheel side disc brakes 6, 6 and the ESC control device 17. The parking brake control device 26 has an arithmetic circuit (CPU) 27 configured by a microcomputer or the like, and the parking brake control device 26 receives electric power from the battery 18 (or a generator driven by an engine) in the power line 19. Powered through.

The parking brake control device 26 controls the drive of the electric motors 7A, 7A of the rear wheel side disc brakes 6, 6 so that the braking force (parking brake, auxiliary brake) is applied when the vehicle is parked or stopped (when traveling as necessary). ) Is generated. That is, the parking brake controller 26 drives the left and right electric motors 7A, 7A to operate (apply/release) the disc brakes 6, 6 as parking brakes (auxiliary brakes as necessary). For this purpose, the parking brake control device 26 has an input side connected to the parking brake switch 25 and an output side connected to the electric motors 7A, 7A of the disc brakes 6, 6.

The parking brake control device 26 determines the left and right sides based on an operation request (apply request, release request) by the driver's operation of the parking brake switch 25, an operation request by an apply/release determination logic of the parking brake, and an operation request by the ABS control. The electric motors 7A, 7A are driven to apply (hold) or release (release) the left and right disc brakes 6, 6. At this time, in the rear wheel side disc brake 6, the pressing member holding mechanism 8 holds or releases the piston 6D and the brake pad 6C based on the drive of each electric motor 7A. In this way, the parking brake control device 26 responds to the operation request signal for holding operation (apply) or releasing operation (release) of the piston 6D (and thus the brake pad 6C), according to the operation request signal. The electric motor 7A is drive-controlled to propel the pad 6C).

As shown in FIG. 3, in the arithmetic circuit 27 of the parking brake control device 26, in addition to the memory 28 as a storage unit, the parking brake switch 25, the vehicle data bus 20, the voltage sensor unit 29, the motor drive circuit 30, the current The sensor unit 31 and the like are connected. From the vehicle data bus 20, various state quantities of the vehicle necessary for controlling (actuating) the parking brake, that is, various vehicle information can be acquired.

The vehicle information obtained from the vehicle data bus 20 may be obtained by directly connecting a sensor that detects the information to (the arithmetic circuit 27 of) the parking brake control device 26. Further, the arithmetic circuit 27 of the parking brake control device 26 is configured so that an operation request based on the above-described determination logic or ABS control is input from another control device (for example, the ESC control device 17) connected to the vehicle data bus 20. You may comprise. In this case, the determination of the apply/release of the parking brake and the control of the ABS by the above-described determination logic may be performed by another control device, for example, the ESC control device 17, instead of the parking brake control device 26. .. That is, it is possible to integrate the control contents of the parking brake control device 26 into the ESC control device 17.

The parking brake control device 26 includes a memory 28 as a storage unit including, for example, a flash memory, a ROM, a RAM, and an EEPROM. The memory 28 stores the above-described parking brake apply/release determination logic and an ABS control program. In addition to this, the memory 28 stores a processing program for executing the processing flow shown in FIG. 4, which will be described later, that is, a processing program used for apply control after automatic braking.

Although the parking brake control device 26 is separate from the ESC control device 17 in the embodiment, the parking brake control device 26 may be integrated with the ESC control device 17. Further, the parking brake control device 26 controls the two rear wheel disc brakes 6, 6 on the left and right, but may be provided on each of the left and right rear wheel disc brakes 6, 6. In this case, each parking brake control device 26 can be provided integrally with the rear wheel side disc brake 6.

As shown in FIG. 3, the parking brake control device 26 includes a voltage sensor unit 29 for detecting a voltage from the power supply line 19, left and right motor drive circuits 30, 30 for driving the left and right electric motors 7A, 7A, and a left and right motor drive circuit 30, respectively. The left and right current sensor units 31 and 31 for detecting the motor currents of the electric motors 7A and 7A are incorporated. The voltage sensor unit 29, the motor drive circuit 30, and the current sensor unit 31 are each connected to the arithmetic circuit 27.

Thereby, the arithmetic circuit 27 of the parking brake control device 26 is based on the change (change in current value) of the motor current of the electric motors 7A and 7A detected by the current sensor units 31 and 31 when applying or releasing. Then, it is possible to determine whether the disc rotor 4 and the brake pad 6C are in contact with each other or separated from each other, and whether the driving of the electric motor 7A is stopped (apply completion determination, release completion determination) or the like.

The parking brake control device 26 is (electrically) connected to the ESC control device 17 via the vehicle data bus 20 or a communication line (not shown) that connects the ESC control device 17 and the parking brake control device 26. ing. In this case, the parking brake control device 26 can control the drive of the electric motor 7A in response to the apply request (braking holding request) from the ESC control device 17. For example, the ESC control device 17 supplies the brake fluid pressure to the disc brakes 5 and 6 by controlling the ESC 15 based on the automatic brake command from the automatic brake control device 23. At this time, when the vehicle stops, the ESC control device 17 outputs an apply request to the parking brake control device 26 as needed (for example, before releasing the brake fluid pressure by the ESC 15). In this case, the parking brake control device 26 drives the electric motor 7A in response to the apply request from the ESC control device 17 while the vehicle is stopped, and sets the disc brake 6 in the apply state (braking holding state).

On the other hand, when the driver tries to start again immediately after the vehicle is stopped by the automatic brake, if the disc brake 6 is set to the apply state based on the apply request from the ESC control device 17, the smooth start of the vehicle is hindered. May be Therefore, in the embodiment, the parking brake control device 26 prohibits the holding of the braking force by the apply request from the ESC control device 17 when the driver's intention to start is detected after the vehicle is stopped. That is, the parking brake control device 26 does not drive the electric motor 7A in response to the apply request from the ESC control device 17 when the driver's willingness to start is detected after the vehicle is stopped.

In this case, the driver's willingness to start is detected by at least one of the accelerator opening degree and the operation for releasing the braking holding state. That is, the parking brake control device 26 operates when the driver's accelerator operation is detected based on the detection signal (accelerator opening) of the accelerator sensor (accelerator operation sensor) acquired via the vehicle data bus 20. It is determined that the person has a willingness to start. For example, when the accelerator opening is 0.5% or more, it is determined that the driver has the will to start. Further, the parking brake control device 26 determines that the driver has the will to start when the driver's release operation (parking brake release operation) is detected by the release request input from the parking brake switch 25. judge. In this case, the parking brake controller 26 also receives the apply request from ESC controller 17, (does not drive the electric motor 7 A to apply side) for prohibiting driving the electric motor 7 A to apply side. The control of the parking brake control device 26, that is, the control of the electric motor 7A when receiving the apply request from the ESC control device 17 will be described later in detail.

The brake system for a four-wheeled vehicle according to the embodiment has the above-described configuration, and its operation will be described next.

When the driver of the vehicle depresses the brake pedal 9, the pedaling force is transmitted to the master cylinder 12 via the booster 11, and the master cylinder 12 generates a brake fluid pressure. The brake fluid pressure generated in the master cylinder 12 is distributed to the disc brakes 5, 6 via the cylinder side fluid pressure pipes 14A, 14B, ESC 15 and the brake side pipe portions 16A, 16B, 16C, 16D, and the left and right front wheels. A braking force is applied to each of the left and right rear wheels 3.

In this case, in each of the disc brakes 5 and 6, the pistons 5B and 6D are slidably displaced toward the brake pad 6C as the brake fluid pressure in the calipers 5A and 6B increases, so that the brake pad 6C is displaced. Pressed against. As a result, the braking force based on the brake fluid pressure is applied. On the other hand, when the brake operation is released, the supply of the brake fluid pressure into the calipers 5A and 6B is stopped, so that the pistons 5B and 6D are displaced away from (retracted from) the disk rotors 4 and 4. As a result, the brake pad 6C is separated from the disc rotors 4 and 4, and the vehicle is returned to the non-braking state.

Next, when the driver of the vehicle operates the parking brake switch 25 to the braking side (apply side), the parking brake control device 26 supplies power to the electric motor 7A of the rear wheel side disk brake 6, and the electric motor 7A. Is driven to rotate. In addition, for example, when the vehicle is stopped by automatic braking, if there is an apply request from the ESC control device 17, the parking brake control device 26 supplies power to the electric motor 7A of the rear wheel side disc brake 6, and the electric motor 7A is rotationally driven.

In the rear wheel side disc brake 6, the rotational movement of the electric motor 7A is converted into a linear movement by the pressing member holding mechanism 8, and the piston 6D is propelled. As a result, the disc pad 4 is pressed by the brake pad 6C. At this time, the pressing member holding mechanism 8 is held in a braking state by, for example, a frictional force (holding force) due to screwing. As a result, the rear wheel side disc brake 6 is operated (applied) as a parking brake. That is, the piston 6D is held at the braking position by the pressing member holding mechanism 8 even after the power supply to the electric motor 7A is stopped.

On the other hand, when the driver operates the parking brake switch 25 to the brake release side (release side), electric power is supplied from the parking brake control device 26 to the electric motor 7A so that the motor reverses. Due to this power supply, the electric motor 7A is rotated in the direction opposite to that when the parking brake is operated (when applied). At this time, the holding of the braking force by the pressing member holding mechanism 8 is released, and the piston 6D can be displaced in the direction away from the disc rotor 4. As a result, the operation of the rear wheel side disc brake 6 as the parking brake is released (released).

Next, the control process performed by the arithmetic circuit 27 of the parking brake control device 26 will be described with reference to FIG. The control process of FIG. 4 is repeatedly executed at a predetermined control cycle, that is, at a predetermined time (for example, 10 ms) while the parking brake control device 26 is energized.

When the parking brake control device 26 is activated, the parking brake control device 26 determines in S1 whether or not there is an apply request (operation request) for the parking brake (PKB) after the automatic braking. That is, in S1, it is determined whether or not an apply request is input from the ESC control device 17 to the parking brake control device 26 via the vehicle data bus 20. Here, the ESC control device 17 supplies the brake fluid pressure to the disc brakes 5 and 6 by controlling the ESC 15 based on the automatic brake command from the automatic brake control device 23, and when the vehicle stops, the parking brake control device. The apply command is output to 26. The parking brake control device 26 determines in S1 whether or not an apply request has been received from the ESC control device 17.

If "NO" in S1, that is, if it is determined that there is no ply request from the ESC control device 17, the process returns to the start via the return, and the processes from S1 are repeated. On the other hand, if “YES” in S1, that is, if it is determined that there is an apply request from the ESC control device 17, the process proceeds to S2. In S2, it is determined whether or not the accelerator pedal is operated. That is, in S2, the parking brake control device 26 determines whether or not the driver operates the accelerator based on the detection signal (accelerator opening degree) of the accelerator sensor (accelerator operation sensor) acquired via the vehicle data bus 20. Determine whether.

If "NO" in S2, that is, if it is determined that the driver does not operate the accelerator, the process proceeds to S3. In S3, it is determined whether or not the parking brake switch (PKB-SW) 25 is released. That is, in S3, it is determined whether or not a release request is input from the parking brake switch 25 to the parking brake control device 26. If "NO" in S3, that is, if it is determined that there is no request to release the parking brake switch 25, the process proceeds to S4. In S4, the parking brake control device 26 drives the electric motor 7A to the Apply side. That is, the parking brake control device 26 performs the apply control for bringing the rear wheel side disc brake 6 into the applied state. When the rear wheel side disc brake 6 is set to the applied state in S4, the process returns to the start via the return, and the processes of S1 and subsequent steps are repeated.

On the other hand, if "YES" in S2, that is, if it is determined that there is an accelerator operation by the driver, the process returns to the start via the return, and the processes from S1 are repeated. Further, also in the case of "YES" in S3, that is, when it is determined that there is a release request for the parking brake switch 25, the process returns to the start via the return, and the processes from S1 onward are repeated. In these cases, it is considered that the driver is trying to start the vehicle (willing to start), and therefore, the process returns to the start without proceeding to S4, that is, without driving the electric motor 7A to the Apply side, and S1 is performed. The subsequent processing is repeated.

In FIG. 4, if “YES” is determined in S2, the process proceeds to return. On the other hand, for example, the configuration may be such that the determination of the engine speed and the determination of the position of the shift lever are performed after determining “YES” in S2. The determination of the engine speed is a determination as to whether the engine is starting (driving). For example, when the engine speed detected by the engine speed sensor and acquired via the vehicle data bus 20 is lower than a predetermined speed set in advance (for example, 300 rpm or less), the engine is stopped. Therefore, it is possible to determine that the driver does not have the will to start even if the accelerator is operated. In this case, that is, when it is determined that the engine is stopped (for example, lower than a predetermined rotation speed), the process proceeds to S3 or S4.

On the other hand, when it is determined that the engine has started (for example, the engine speed is equal to or higher than the predetermined rotation speed), the position of the shift lever is determined. The determination of the position of the shift lever is a determination of whether or not the shift lever is at a position other than P and N. For example, when the position of the shift lever detected by the shift sensor and acquired via the vehicle data bus 20 is P or N, even if the engine is started and the accelerator is operated, the driver willing to start. There can be no. In this case, that is, when it is determined that the position of the shift lever is P or N, the process proceeds to S3 or S4. On the other hand, when the position of the shift lever is other than P and N, it is determined that the driver has a will to start (determine the will to start), and the process proceeds to return (the drive of the electric motor 7A in the apply direction is prohibited).

Thus, in the embodiment, even if it is determined that there is a ply request from the ESC control device 17 in S1 of FIG. 4, “YES” in S2 of FIG. 4 or “YES” in S3. If it is determined that the driver's willingness to start is detected, the process does not proceed to S4. That is, when the driver's willingness to start is detected after the vehicle is stopped, the parking brake control device 26 prohibits the holding of the braking force by the apply request even if the ESC control device 17 requests the apply. To do. In other words, when the driver's willingness to start is detected after the vehicle has stopped, the electric motor 7A is not driven to the Apply side even if there is an Apply request from the ESC control device 17. Therefore, the piston 6D is not propelled by the electric motor 7A, and the rear wheel side disc brake 6 maintains the released state. As a result, the driver's willingness to start is prioritized, and the vehicle can be started smoothly.

FIG. 5 shows an example of changes over time in vehicle speed, accelerator pedal operation, apply request from the ESC control device 17, and parking brake operation. When the electric motor 7A is driven to the Apply side in accordance with the Apply request from the ESC control device 17, the rear wheel side disc brake 6 is in the Apply state, as indicated by a broken line 41 in FIG. In this case, although the accelerator pedal is operated, the rear wheel side disc brake 6 is in the applied state, which may hinder the smooth start of the vehicle. On the other hand, in the embodiment, if it is determined to be “YES” in S2 of FIG. 4, the electric motor 7A is not driven to the Apply side. Therefore, as shown by the solid characteristic line 42 in FIG. 5, the released state of the rear wheel side disc brake 6 is maintained. As a result, the vehicle can be started smoothly.

In the embodiment, the parking brake control device 26 detects the driver's intention to start by the accelerator operation (accelerator opening degree) of the driver and the release operation of the parking brake switch 25. That is, in S2 of FIG. 4, the driver's intention to start is detected based on the presence/absence of accelerator operation by the driver. Further, in S3 of FIG. 4, the driver's willingness to start is detected from the presence or absence of the release request of the parking brake switch 25. Therefore, the driver's willingness to start can be reliably detected.

In the embodiment, the braking force control device for controlling the braking force by controlling the hydraulic pressure supply to the pistons 5B, 6D of the disc brakes 5, 6 is a control device of the ESC 15 which is a hydraulic pressure supply device, that is, The case where the ESC control device 17 is used has been described as an example. However, the invention is not limited to this, and the braking force control device may be, for example, a control device of an electric booster that controls the hydraulic pressure of the master cylinder, that is, an electric boost control device.

In the embodiment, the case where the left and right rear wheel disc brakes 6 are disc brakes with an electric parking brake function has been described as an example. However, the invention is not limited to this, and the left and right front wheel disc brakes 5 may be disc brakes with an electric parking brake function. Further, the brakes for all the front wheels and the rear wheels (all four wheels) may be configured by disc brakes with an electric parking brake function. That is, the brakes of at least one pair of wheels of the vehicle can be configured by the disc brakes with the electric parking brake function.

In the embodiment, as the parking brake device (electric parking brake mechanism), the hydraulic disc brake 6 with the electric parking brake has been described as an example. However, the brake mechanism is not limited to the disc brake type brake mechanism, and may be configured as a drum brake type brake mechanism. Further, various brake mechanisms can be adopted, such as a drum-in disc brake in which a drum-type electric parking brake is provided in the disc brake, and a configuration in which the parking brake is held by pulling a cable with an electric motor.

As the brake device and the brake system based on the above-described embodiment, for example, the following modes are conceivable.

(1). As a first aspect, the braking force control is connected to an electric motor that propels a piston that presses the braking member against the braked member, and a braking force control device that controls the hydraulic pressure supply to the piston to control the braking force. A motor control device that controls the drive of the electric motor in response to a braking holding request from the device, and the motor control device controls the braking force when the driver's willingness to start is detected after the vehicle is stopped. It is prohibited to hold the braking force by the braking holding request from the device.

According to the first aspect, when the driver's willingness to start is detected after the vehicle is in the stopped state, the electric motor control device determines whether or not the braking force is requested by the braking force control device. The holding of braking force by is prohibited. Therefore, the piston is not propelled by the electric motor, the driver's intention to start is prioritized, and the vehicle can be started smoothly.

(2). As a second aspect, in the first aspect, the driver's willingness to start is detected by at least one of an accelerator opening degree and a brake holding state release operation.

According to the second aspect, the driver's willingness to start can be reliably detected.

(3). As a third aspect, an electric motor that propels a piston that presses a braking member against a member to be braked, an electric motor control device that controls driving of the electric motor, and a control that controls hydraulic pressure supply to the piston to control braking force. The electric motor control device is a brake system for driving the electric motor in response to a braking holding request from the braking force control device to drive the electric motor to be in the braking holding state when the vehicle is stopped. If the driver's willingness to start is detected after the vehicle has stopped, the electric motor is not driven by a braking holding request from the braking force control device.

According to the third aspect, the electric motor control device drives the electric motor even when the braking force request is issued from the braking force control device when the driver's intention to start is detected after the vehicle is stopped. do not do. Therefore, the piston is not propelled by the electric motor, the driver's intention to start is prioritized, and the vehicle can be started smoothly.

(4). As a fourth aspect, in the third aspect, the driver's willingness to start is detected by at least one of an accelerator opening degree and a brake holding state release operation.

According to the fourth aspect, the driver's willingness to start can be reliably detected.

4 Disc rotor (braked member)
6 Rear wheel side disc brake 6C Brake pad (braking member)
6D Piston 7A Electric motor (electric motor)
8 Pressing member holding mechanism (holding mechanism)
17 ESC control device (braking force control device)
26 Parking brake control device (electric motor control device)

Claims (4)

An electric motor that propels a piston that presses the braking member against the braked member,
An electric motor control device that is connected to a braking force control device that controls the hydraulic pressure supply to the piston to control the braking force, and that controls the drive of the electric motor according to a braking holding request from the braking force control device. Prepare,
The electric motor control device prohibits the holding of the braking force when a braking holding request is output from the braking force control device when the driver's intention to start is detected after the vehicle is stopped. Characteristic braking device. The starting intention of the driver, the brake device according to claim 1, characterized in that it is detected by at least one of the release operation of Braking holding state and the accelerator opening. An electric motor that propels a piston that presses the braking member against the braked member,
An electric motor control device for controlling the drive of the electric motor;
A braking force control device for controlling the braking force by controlling the hydraulic pressure supply to the piston,
The electric motor control device is a brake system for driving the electric motor in response to a braking holding request from the braking force control device when the vehicle is stopped to bring the electric motor into a braking holding state,
The electric motor control device does not drive the electric motor in response to an output of a braking holding request from the braking force control device when the driver's intention to start is detected after the vehicle is stopped. Brake system to do. The brake system according to claim 3, wherein the driver's willingness to start is detected by at least one of an accelerator opening degree and a release operation of the braking holding state.

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