JP6418639B2 - Brake device - Google Patents

Description

  The present invention relates to a brake device that applies a braking force to a vehicle.

  As a brake device provided in a vehicle such as an automobile, a brake device that operates based on driving of an electric motor is known (Patent Document 1). Here, Patent Document 1 discloses a technique for suppressing a voltage drop by shifting the start timing of the electric motor on the left side of the vehicle body and the start timing of the electric motor on the right side of the vehicle body when applying the parking brake. Have been described.

JP 2014-46824 A

  According to Patent Literature 1, when applying the parking brake, by shifting the start timing of the electric motor left and right, for example, it is possible to suppress a voltage drop due to overlapping of start currents (rush currents). However, when the parking brake is released, if the start timing is shifted left and right simply from the viewpoint of suppressing the voltage drop, for example, depending on the state of the electric motor at that time, the thrust actually decreases in the brake mechanism from the start of release. There may be a difference in left and right (shift) in the time to start. In this case, the vehicle is shaken in the lateral direction due to the difference between the left and right sides, and there is a possibility that the passengers (occupants) such as the driver feel uncomfortable and uncomfortable.

  The objective of this invention is providing the brake device which can suppress the discomfort at the time of release.

  In order to solve the above-described problems, a brake device according to the present invention includes a drive unit that performs an apply drive that applies a braking force to a vehicle by supplying a current to an electric motor and a release drive that releases the braking force. In the brake device for each of the left and right wheels, a state quantity calculation unit that calculates a state quantity of each motor in the left and right wheels while the apply drive is being performed, and a state that is calculated by the state quantity calculation unit And a control unit that controls each of the motors so as to reduce the time difference between the left and right wheels until the wheels become rotatable by the release drive of the left and right wheels based on the amount.

  According to the brake device of the present invention, a sense of incongruity at the time of release can be suppressed.

The conceptual diagram of the vehicle carrying the brake device by 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 flowchart which shows the process which calculates the motor rotation amount integrated value on the left side. The flowchart which shows the process which calculates the motor rotation amount integrated value on the right side. The characteristic view which shows an example of the time change of the state of an electric current, thrust, motor rotation amount integrated value, and a parking brake. The flowchart which shows the control processing of the release by 1st Embodiment. 8 is a flowchart showing “delay time determination processing” in FIG. 7. FIG. 8 is a flowchart showing “delay wheel determination processing” in FIG. 7. FIG. 8 is a flowchart showing “control start timing shifting process (left)” in FIG. 7; FIG. 8 is a flowchart showing “control start timing shifting process (right)” in FIG. 7; The characteristic view which shows an example of the relationship (table) of the right-and-left difference of motor rotation amount integrated value, and delay time. The characteristic view which shows an example of the time change of the electric current of both the left-wheel side and right-wheel side by 1st Embodiment, thrust, motor rotation amount integrated value, and the state of a parking brake. The characteristic view which shows an example of the time change of the electric current of both the left-wheel side by the comparative example, and the right-wheel side, thrust, motor rotation amount integrated value, and the state of a parking brake. 10 is a flowchart showing release control processing according to the second embodiment; The flowchart which shows the "switching control start timing determination process (left)" in FIG. The flowchart which shows the "switching control start timing determination process (right)" in FIG. The flowchart which shows the "switching control start process (left)" in FIG. The flowchart which shows the "switching control start process (right)" in FIG. FIG. 6 is a characteristic diagram showing an example of a relationship (table) between a motor rotation amount integrated value when the motor is stopped in a locked state and a motor rotation amount integrated value (motor rotation amount threshold value) for starting switching control during release. An example of time change of current and thrust when performing only delay time control, when performing delay time control and switching control, and when performing delay time control, switching control and start timing control is shown. Characteristic diagram. The flowchart similar to FIG. 9 which shows the "delayed wheel determination process" by a modification.

  Hereinafter, the brake device according to the embodiment will be described with reference to the accompanying drawings, taking as an example a case where the brake device is mounted on a four-wheeled vehicle. 4, 5, 7 to 11, 15 to 19, and 22, each step in the flowchart uses the notation “S”, for example, step 1 is indicated as “S1”. To do.

  1 to 13 show a first embodiment. In FIG. 1, on the lower side (road surface side) of the vehicle body 1 constituting the vehicle body, for example, a total of four front wheels 2 (FL, FR) and left and right rear wheels 3 (RL, RR). Wheels are provided. The front wheel 2 and the rear wheel 3 are provided with a disc rotor 4 as a braked member (rotating member) that rotates together with the respective wheels (the front wheels 2 and the rear wheels 3). The disc rotor 4 for the front wheel 2 is given a braking force by a hydraulic disc brake 5, and the disc rotor 4 for the rear wheel 3 is given a braking force by a hydraulic disc brake 31 with an electric parking brake function. The Thereby, a braking force is applied to each wheel (each front wheel 2, each rear wheel 3) independently of each other.

  A brake pedal 6 is provided on the front board side of the vehicle body 1. The brake pedal 6 is depressed by the driver during the braking operation of the vehicle. Based on this operation, the disc brakes 5 and 31 are applied and released as a service brake (service brake). The brake pedal 6 is provided with a brake operation detection sensor (brake sensor) 6A such as a brake lamp switch, a pedal switch, and a pedal stroke sensor. The brake operation detection sensor 6 </ b> A detects whether or not the brake pedal 6 is depressed, or the operation amount thereof, and outputs a detection signal to the hydraulic pressure supply controller 13. The detection signal of the brake operation detection sensor 6A is transmitted, for example, via a vehicle data bus 16 or a signal line (not shown) connecting the hydraulic pressure supply device controller 13 and the parking brake control device 19 ( Is output to the parking brake control device 19).

  The depression operation of the brake pedal 6 is transmitted to the master cylinder 8 that functions as a hydraulic pressure source via the booster 7. The booster 7 is configured as a negative pressure booster or an electric booster provided between the brake pedal 6 and the master cylinder 8, and increases the pedal force when the brake pedal 6 is depressed and transmits it to the master cylinder 8. At this time, the master cylinder 8 generates hydraulic pressure with the brake fluid supplied from the master reservoir 9. The master reservoir 9 is composed of a hydraulic fluid tank that stores brake fluid. The mechanism for generating the hydraulic pressure by the brake pedal 6 is not limited to the above configuration, and a mechanism for generating the hydraulic pressure in response to the operation of the brake pedal 6, for example, a brake-by-wire mechanism or the like may be used. .

  The hydraulic pressure generated in the master cylinder 8 is sent to a hydraulic pressure supply device 11 (hereinafter referred to as ESC 11) via, for example, a pair of cylinder side hydraulic pipes 10A and 10B. The ESC 11 is disposed between each of the disc brakes 5, 31 and the master cylinder 8, and distributes the hydraulic pressure from the master cylinder 8 to each of the disc brakes 5, 31 via the brake side piping portions 12A, 12B, 12C, 12D. To do. Thereby, a braking force is applied to each of the wheels (each front wheel 2 and each rear wheel 3) independently of each other. In this case, even if the ESC 11 does not follow the operation amount of the brake pedal 6, the ESC 11 can supply the hydraulic pressure to the disc brakes 5, 31, that is, increase the hydraulic pressure of the disc brakes 5, 31.

  For this purpose, the ESC 11 has a dedicated control device configured by, for example, a microcomputer, that is, a hydraulic pressure supply device controller 13 (hereinafter referred to as a control unit 13). The control unit 13 opens and closes each control valve (not shown) of the ESC 11 and performs drive control to rotate and stop an electric motor (not shown) for the hydraulic pump, thereby controlling the brake side. Control is performed to increase, decrease or maintain the brake fluid pressure supplied from the piping parts 12A to 12D to the respective disc brakes 5, 31. 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 operation control or the like is executed.

  The control unit 13 is supplied with power from the battery 14 through the power supply line 15. As shown in FIG. 1, the control unit 13 is connected to a vehicle data bus 16. A known ABS unit can be used instead of the ESC 11. Furthermore, it is also possible to directly connect the master cylinder 8 and the brake side piping parts 12A to 12D without providing the ESC 11 (that is, omitted).

  The vehicle data bus 16 constitutes a CAN (Controller Area Network) as a serial communication unit mounted on the vehicle body 1, and includes a large number of electronic devices mounted on the vehicle, the control unit 13, the parking brake control device 19, and the like. Multiplex communication within the vehicle. In this case, vehicle information sent to the vehicle data bus 16 includes, for example, a brake operation detection sensor 6A, a pressure sensor 17 for detecting a master cylinder hydraulic pressure (brake hydraulic pressure), an ignition switch, a seat belt sensor, a door lock sensor, Door open sensor, seating sensor, vehicle speed sensor, steering angle sensor, accelerator sensor (accelerator operation sensor), throttle sensor, engine rotation sensor, stereo camera, millimeter wave radar, gradient sensor, shift sensor, acceleration sensor, wheel speed sensor, vehicle The information (vehicle information) by the detection signal from the pitch sensor etc. which detect the motion of the pitch direction of this is mentioned.

  In the vehicle body 1, a parking brake switch (PKBSW) 18 is provided in the vicinity of a driver's seat (not shown). The parking brake switch 18 is operated by the driver. The parking brake switch 18 transmits a signal (operation request signal) corresponding to a parking brake operation request (apply request, release request) from the driver to the parking brake control device 19. That is, the parking brake switch 18 generates signals (apply request signal, release request signal) for applying or releasing the brake pad 33 (see FIG. 2) based on the drive (rotation) of the electric motor 43B. It outputs to the parking brake control apparatus 19 used as (controller).

  When the driver operates the parking brake switch 18 to the braking side (parking brake ON side), that is, when there is an apply request (holding request, driving request) for applying braking force to the vehicle, the parking brake switch An apply request signal is output from 18. In this case, the electric power for rotating the electric motor 43 </ b> B to the braking side is supplied to the disc brake 31 for the rear wheel 3 through the parking brake control device 19. Accordingly, the disc brake 31 for the rear wheel 3 is in a state where a braking force as a parking brake (or auxiliary brake) is applied, that is, in an applied state.

  On the other hand, when the driver operates the parking brake switch 18 to the braking release side (parking brake OFF side), that is, when there is a release request (release request) for releasing the braking force of the vehicle, the parking brake A release request signal is output from the switch 18. In this case, electric power for rotating the electric motor 43B in the direction opposite to the braking side is supplied to the disc brake 31 via the parking brake control device 19. As a result, the disc brake 31 for the rear wheel 3 is in a state in which the application of the braking force as the parking brake (or auxiliary brake) is released, that is, in the released state.

  For example, when the vehicle is stopped for a predetermined time (for example, when the vehicle is decelerated during traveling, the engine is stopped when the vehicle speed sensor detects that the speed detected by the vehicle speed sensor is less than 4 km / h for a predetermined time). When the shift lever is operated to P, when the door is opened, when the seat belt is released, etc., based on the automatic apply request by the parking brake apply determination logic in the parking brake control device 19, It can be configured to automatically give (auto apply). In addition, the parking brake is used when, for example, the vehicle travels (for example, it is determined that the vehicle travels when the detection speed of the vehicle speed sensor is 5 km / h or more continues for a predetermined time as the vehicle speed increases from when the vehicle is stopped). Is operated, when the clutch pedal is operated, when the shift lever is operated other than P, N, etc., based on the automatic release request by the parking brake release determination logic in the parking brake control device 19 It can be configured to automatically release (auto release).

  Further, when there is an apply request by the parking brake switch 18 during traveling of the vehicle, more specifically, a request for dynamic parking brake (dynamic apply) such as urgently using the parking brake as an auxiliary brake during traveling. When there is a braking force, the parking brake control device 19 automatically applies and releases the braking force according to the state of the wheel (each rear wheel 3), that is, whether or not the wheel is locked (slip) ( (ABS control) can also be performed.

  Next, the structure of the disc brakes 31 and 31 with the electric parking brake function provided on the left and right rear wheels 3 and 3 will be described with reference to FIG. In FIG. 2, only one of the left and right disc brakes 31, 31 provided corresponding to the left and right rear wheels 3, 3 is shown as a representative example.

  A pair of disc brakes 31 provided on the left and right sides of the vehicle are configured as hydraulic disc brakes provided with an electric parking brake function. The disc brake 31 constitutes a brake system (brake device) together with the parking brake control device 19. The disc brake 31 includes a mounting member 32 attached to a non-rotating part on the rear wheel 3 side of the vehicle, an inner side and outer side brake pad 33 as a braking member (friction member), and a brake provided with an electric actuator 43. It includes a caliper 34 as a mechanism.

  In this case, the disc brake 31 extends the wheel (rear wheel 3) by propelling the brake pad 33 with the piston 39 by the hydraulic pressure based on the operation of the brake pedal 6 and the like, and pressing the disc rotor 4 with the brake pad 33. Applies braking force to the vehicle. In addition to this, the disc brake 31 is rotated (rotated) by the electric motor 43B in response to an operation request based on a signal from the parking brake switch 18, an application / release determination logic of the parking brake, and an operation request based on ABS control. The piston 39 is propelled (via the linear motion conversion mechanism 40) to apply a braking force to the vehicle. That is, the disc brake 31 serves as a drive unit that performs an apply drive that applies a braking force to the vehicle by supplying a current to the electric motor 43B and a release drive that releases the braking force. In this case, the disc brake 31 is provided on each of the left and right wheels of the vehicle, in the embodiment, on the left and right rear wheels 3 and 3, respectively.

  The mounting member 32 includes a pair of arm portions (not shown) that extend in the axial direction of the disk rotor 4 (that is, the disk axial direction) so as to straddle the outer periphery of the disk rotor 4, and are separated from each other in the disk circumferential direction. A thick-walled support portion 32A that is fixed to a non-rotating portion of the vehicle at a position on the inner side of the disk rotor 4 and is connected to the base end side of the disk rotor 4; And a reinforcing beam 32B for connecting the distal end sides of the arm portions to each other.

  The brake pads 33 on the inner side and the outer side are disposed so as to be able to contact both surfaces of the disk rotor 4 and are supported by the respective arm portions of the mounting member 32 so as to be movable in the disk axial direction. The brake pads 33 on the inner side and the outer side are pressed against both sides of the disc rotor 4 by calipers 34 (the claw portions 38 and the pistons 39 of the caliper main body 35). Thereby, the brake pad 33 gives a braking force to the vehicle by pressing the disc rotor 4 that rotates together with the wheels (rear wheels 3).

  A caliper 34 serving as a wheel cylinder is disposed on the mounting member 32 so as to straddle the outer peripheral side of the disk rotor 4. The caliper 34 is provided so as to be slidably inserted into the caliper body 35 supported so as to be movable along the axial direction of the disk rotor 4 with respect to each arm portion of the mounting member 32. In addition to the piston 39, a rotation / linear motion conversion mechanism 40, an electric actuator 43, and the like, which will be described later, are provided. The caliper 34 propels the brake pad 33 using a piston 39 that is operated by the hydraulic pressure generated in the master cylinder 8 based on the operation of the brake pedal 6.

  The caliper body 35 includes an inner cylinder portion 36, a bridge portion 37, and an outer claw portion 38. The cylinder portion 36 is formed in a bottomed cylindrical shape in which one side in the axial direction is closed by a partition wall portion 36 </ b> A and the other side facing the disk rotor 4 is opened. The bridge portion 37 is formed to extend from the cylinder portion 36 in the disc axial direction so as to straddle the outer peripheral side of the disc rotor 4. The claw portion 38 is disposed so as to extend radially inward from the bridge portion 37 on the side opposite to the cylinder portion 36.

  The cylinder portion 36 of the caliper main body 35 is supplied with hydraulic pressure accompanying the depression operation of the brake pedal 6 or the like via the brake side piping portion 12C or 12D shown in FIG. The cylinder portion 36 is integrally formed with the partition wall portion 36A. The partition wall portion 36 </ b> A is located between the cylinder portion 36 and the electric actuator 43. The partition wall portion 36A has a through hole in the axial direction, and an output shaft 43C of the electric actuator 43 is rotatably inserted on the inner peripheral side of the partition wall portion 36A.

  In the cylinder portion 36 of the caliper main body 35, a piston 39 as a pressing member (moving member) and a rotation / linear motion conversion mechanism 40 are provided. In the embodiment, the rotation / linear motion conversion mechanism 40 is accommodated in the piston 39. However, the rotation / linear motion conversion mechanism 40 may be configured to propel the piston 39 and may not necessarily be accommodated in the piston 39.

  The piston 39 moves the brake pad 33 toward the disk rotor 4 or in a direction away from the disk rotor 4. The piston 39 is open on one side in the axial direction, and the other side in the axial direction facing the inner brake pad 33 is closed by a lid portion 39A. The piston 39 is inserted into the cylinder part 36. In addition to the movement of the piston 39 when electric current is supplied to the electric actuator 43 (electric motor 43B), the hydraulic pressure is supplied into the cylinder portion 36 based on the depression of the brake pedal 6 or the like. Moving. In this case, the movement of the piston 39 by the electric actuator 43 (electric motor 43B) is performed by being pressed by the linear motion member. Further, the rotation / linear motion conversion mechanism 40 is accommodated in a piston 39, and the piston 39 is configured to be propelled in the axial direction of the cylinder portion 36 by the rotation / linear motion conversion mechanism 40.

  The rotation / linear motion conversion mechanism 40 functions as a pressing member holding mechanism. Specifically, the rotation / linear motion conversion mechanism 40 propels the piston 39 of the caliper 34 by an external force different from the force generated by the addition of the hydraulic pressure into the cylinder portion 36, that is, the force generated by the electric actuator 43. The propelled piston 39 and the brake pad 33 are held. Thereby, a parking brake will be in an applied state (holding state). On the other hand, the rotation / linear motion conversion mechanism 40 retracts the piston 39 in the direction opposite to the propulsion direction by the electric actuator 43, and sets the parking brake to the released state (released state). Since the left and right disc brakes 31 are respectively provided for the left and right rear wheels 3, the rotation / linear motion conversion mechanism 40 and the electric actuator 43 are also provided on each of the left and right sides of the vehicle.

  The rotation / linear motion conversion mechanism 40 includes a screw member 41 having a rod-like body in which a male screw such as a trapezoidal screw is formed, and a linear motion member 42 in which a female screw hole formed by the trapezoidal screw is formed on the inner peripheral side (spindle). Configured as a nut mechanism). The linear motion member 42 is a driven member (propulsion member) that moves toward the piston 39 by the electric actuator 43 or in a direction away from the piston 39. That is, the screw member 41 screwed to the inner peripheral side of the linear motion member 42 constitutes a screw mechanism that converts the rotational motion by the electric actuator 43 into the linear motion of the linear motion member 42. In this case, the female screw of the linear motion member 42 and the male screw of the screw member 41 form a pressing member holding mechanism by using a highly irreversible screw, in the embodiment, a trapezoidal screw.

  The pressing member holding mechanism (rotation / linear motion converting mechanism 40) holds the linear motion member 42 (that is, the piston 39) at an arbitrary position by a frictional force (holding force) even when power supply to the electric motor 43B is stopped. It has become. The pressing member holding mechanism only needs to be able to hold the piston 39 at a position propelled by the electric actuator 43. For example, the pressing member holding mechanism may be a normal triangular cross-section screw or a worm gear having a large irreversibility other than a trapezoidal screw.

  The screw member 41 that is screwed to the inner peripheral side of the linear motion member 42 is provided with a flange portion 41A that is a large-diameter flange on one side in the axial direction. The other side of the screw member 41 in the axial direction extends toward the lid portion 39 </ b> A of the piston 39. The screw member 41 is integrally connected to the output shaft 43C of the electric actuator 43 at the flange portion 41A. Further, on the outer peripheral side of the linear motion member 42, the linear motion member 42 is prevented from rotating with respect to the piston 39 (relative rotation is restricted), and the linear motion member 42 is allowed to relatively move in the axial direction. A protrusion 42A is provided. Thereby, the linear motion member 42 moves linearly when the electric motor 43B is driven, contacts the piston 39, and moves the piston 39.

  The electric actuator 43 is fixed to the caliper body 35 of the caliper 34. The electric actuator 43 operates (applies and releases) the disc brake 31 based on the operation request signal of the parking brake switch 18, the above-described parking brake apply / release determination logic, and ABS control. The electric actuator 43 includes a casing 43A attached to the outside of the partition wall portion 36A, an electric motor 43B that is positioned in the casing 43A and moves the piston 39 when supplied with electric power (current). And a reduction gear (not shown) that increases the torque of the electric motor 43B, and an output shaft 43C that outputs the increased rotational torque by the reduction gear. The electric motor 43B is configured as an electric motor such as a DC brush motor, for example. The output shaft 43C extends through the partition wall portion 36A of the cylinder portion 36 in the axial direction, and at the end of the flange portion 41A of the screw member 41 in the cylinder portion 36 so as to rotate integrally with the screw member 41. It is connected.

  For example, the coupling mechanism between the output shaft 43C and the screw member 41 can be configured to be movable in the axial direction but to be prevented from rotating in the rotational direction. In this case, a known technique such as spline fitting or fitting with a polygonal column (non-circular fitting) is used. As the speed reducer, for example, a planetary gear speed reducer or a worm gear speed reducer may be used. Further, when a known speed reducer having no reverse operation (irreversible) such as a worm gear speed reducer is used, the reversible known mechanism such as a ball screw or a ball ramp mechanism is used as the rotation / linear motion converting mechanism 40. Can be used. In this case, for example, the pressing member holding mechanism can be configured by a reversible rotation / linear motion conversion mechanism and an irreversible speed reducer.

  When the driver operates the parking brake switch 18 shown in FIGS. 1 to 3, electric power is supplied to the electric motor 43 </ b> B via the parking brake control device 19, and the output shaft 43 </ b> C of the electric actuator 43 is rotated. For this reason, the screw member 41 of the rotation / linear motion conversion mechanism 40 is rotated integrally with the output shaft 43C in one direction, and propels (drives) the piston 39 toward the disk rotor 4 via the linear motion member 42. As a result, the disc brake 31 is in a state where the disc rotor 4 is sandwiched between the inner side and outer side brake pads 33 and a braking force is applied as an electric parking brake, that is, in an applied state (holding state).

  On the other hand, when the parking brake switch 18 is operated to the brake release side, the screw member 41 of the rotation / linear motion conversion mechanism 40 is driven to rotate in the other direction (reverse direction) by the electric actuator 43. As a result, the linear motion member 42 (and the piston 39 if no hydraulic pressure is applied) is driven in a direction away from the disc rotor 4, and the disc brake 31 is in a state in which the application of the braking force as a parking brake is released, that is, , The release state (release state).

  In this case, in the rotation / linear motion converting mechanism 40, when the screw member 41 is rotated relative to the linear motion member 42, the rotation of the linear motion member 42 within the piston 39 is restricted. Moves relatively in the axial direction according to the rotation angle of the screw member 41. Thereby, the rotation / linear motion converting mechanism 40 converts the rotational motion into a linear motion, and the piston 39 is driven by the linear motion member 42. At the same time, the rotation / linear motion conversion mechanism 40 holds the linear motion member 42 at an arbitrary position by a frictional force with the screw member 41, so that the piston 39 and the brake pad 33 are propelled by the electric actuator 43. Hold on.

  A thrust bearing 44 is provided on the partition wall portion 36 </ b> A of the cylinder portion 36 between the partition wall portion 36 </ b> A and the flange portion 41 </ b> A of the screw member 41. The thrust bearing 44 receives a thrust load from the screw member 41 together with the partition wall portion 36A, and smoothly rotates the screw member 41 with respect to the partition wall portion 36A. In addition, a seal member 45 is provided between the partition wall portion 36A of the cylinder portion 36 and the output shaft 43C of the electric actuator 43. The seal member 45 leaks brake fluid in the cylinder portion 36 to the electric actuator 43 side. It seals between the two so as to prevent it.

  A piston seal 46 as an elastic seal that seals between the cylinder portion 36 and the piston 39 and a dust boot 47 that prevents foreign matter from entering the cylinder portion 36 are provided on the opening end side of the cylinder portion 36. It has been. The dust boot 47 is a flexible bellows-like seal member, and is attached between the opening end of the cylinder portion 36 and the outer periphery of the piston 39 on the lid portion 39A side.

  The disc brake 5 for the front wheel 2 is configured in substantially the same manner as the disc brake 31 for the rear wheel 3 except for the parking brake mechanism. That is, the disc brake 5 for the front wheel 2 does not include the rotation / linear motion conversion mechanism 40 that operates as a parking brake, the electric actuator 43, and the like provided in the disc brake 31 for the rear wheel 3. However, instead of the disc brake 5, a disc brake 31 with an electric parking brake function may be provided for the front wheel 2.

  In the embodiment, the hydraulic disc brake 31 having the electric actuator 43 has been described as an example. However, for example, an electric disc brake having an electric caliper, an electric drum brake that applies a braking force by pressing a shoe against the drum by an electric actuator, a disc brake having an electric drum type parking brake, and a cable being pulled by an electric actuator The brake member (pad, shoe) is pressed (promoted) against the member to be braked (rotor, drum) based on the driving of the electric actuator (electric motor), such as the configuration in which the parking brake is applied, and the pressing force is As long as the brake mechanism can be held, the configuration may not be the brake mechanism of the above-described embodiment.

  The brake device for a four-wheeled vehicle according to the embodiment has the above-described configuration. Next, the operation thereof will be described.

  When the driver of the vehicle depresses the brake pedal 6, the pedaling force is transmitted to the master cylinder 8 via the booster 7, and brake fluid pressure is generated by the master cylinder 8. The hydraulic pressure generated in the master cylinder 8 is distributed to the disc brakes 5 and 31 via the cylinder side hydraulic pipes 10A and 10B, the ESC 11 and the brake side pipe sections 12A, 12B, 12C and 12D, and the left and right front wheels 2 A braking force is applied to each of the left and right rear wheels 3.

  The disc brake 31 for the rear wheel 3 will be described. The hydraulic pressure is supplied into the cylinder portion 36 of the caliper 34 via the brake side piping portions 12C and 12D, and the piston 39 is slidably displaced toward the brake pad 33 on the inner side as the hydraulic pressure in the cylinder portion 36 increases. To do. Accordingly, the piston 39 presses the inner brake pad 33 against one side surface of the disk rotor 4. Due to the reaction force at this time, the entire caliper 34 is slidably displaced toward the inner side with respect to the respective arm portions of the mounting member 32.

  As a result, the outer leg portion (claw portion 38) of the caliper 34 operates so as to press the brake pad 33 on the outer side against the disc rotor 4, and the disc rotor 4 is moved in the axial direction by the pair of brake pads 33. It is clamped from both sides. Thereby, a braking force based on the hydraulic pressure is generated. On the other hand, when the brake operation is released, the supply of the hydraulic pressure into the cylinder portion 36 is stopped, so that the piston 39 is displaced so as to retract into the cylinder portion 36. As a result, the inner-side and outer-side brake pads 33 are separated from the disc rotor 4, and the vehicle is returned to the non-braking state.

  Next, when the driver of the vehicle operates the parking brake switch 18 to the braking side (ON), power is supplied from the parking brake control device 19 to the electric motor 43B of the disc brake 31, and the output shaft 43C of the electric actuator 43 is Driven by rotation. The disc brake 31 with the electric parking brake function converts the rotational motion of the electric actuator 43 into the linear motion of the linear motion member 42 via the screw member 41 of the rotational linear motion conversion mechanism 40, and the linear motion member 42 in the axial direction. The piston 39 is propelled by moving it. As a result, the pair of brake pads 33 are pressed against both surfaces of the disc rotor 4.

  At this time, the linear motion member 42 is held in a braking state by a frictional force (holding force) generated between the linear motion member 42 and the screw member 41 using the pressing reaction force transmitted from the piston 39 as a vertical reaction force. The disc brake 31 is operated (applied) as a parking brake. That is, even after the power supply to the electric motor 43B is stopped, the linear motion member 42 (and hence the piston 39) can be held in the braking position by the female screw of the linear motion member 42 and the male screw of the screw member 41.

  On the other hand, when the driver operates the parking brake switch 18 to the brake release side (off), electric power is supplied from the parking brake control device 19 so as to reverse the motor to the electric motor 43B, and the output shaft 43C of the electric actuator 43 is When the parking brake is activated (apply), it is rotated in the opposite direction. At this time, the holding of the braking force by the screw member 41 and the linear motion member 42 is released, and the rotation / linear motion conversion mechanism 40 moves the linear motion member 42 in the return direction by a movement amount corresponding to the reverse rotation amount of the electric actuator 43. That is, it is moved into the cylinder portion 36, and the braking force of the parking brake (disc brake 31) is released.

  Next, the parking brake control device 19 will be described with reference to FIG.

  The parking brake control device 19 as a control unit, a state quantity calculation unit, a timing determination unit, a storage unit, and a detection unit constitutes an electric brake system (brake device) together with a pair of left and right disc brakes 31, 31. The parking brake control device 19 has an arithmetic circuit (CPU) 20 configured by a microcomputer or the like, and the parking brake control device 19 is supplied with power from the battery 14 through the power supply line 15.

  The parking brake control device 19 controls the electric motors 43B and 43B of the disc brakes 31 and 31 on the left rear wheel 3 side and the right rear wheel 3 side to control when the vehicle is parked or stopped (when necessary, traveling). Generate power (parking brake, auxiliary brake). That is, the parking brake control device 19 operates (applies and releases) the disc brakes 31 and 31 as parking brakes (auxiliary brakes as necessary) by driving the left and right electric motors 43B and 43B. For this purpose, as shown in FIGS. 1 to 3, the parking brake control device 19 has an input side connected to the parking brake switch 18 and an output side connected to the electric motors 43B and 43B of the disc brakes 31 and 31, respectively. Yes.

  The parking brake control device 19 determines the right and left based on the operation request (apply request, release request) by the driver's operation of the parking brake switch 18, the operation request by the apply / release judgment logic of the parking brake, and the operation request by ABS control. The electric motors 43B and 43B are driven to apply (hold) or release (release) the left and right disc brakes 31 and 31. At this time, in each of the disc brakes 31, 31, the piston 39 and the brake pad 33 are held or released by the pressing member holding mechanism (rotation linear motion conversion mechanism 40) based on the driving of each electric motor 43 </ b> B.

  As shown in FIG. 3, the arithmetic circuit (CPU) 20 of the parking brake control device 19 includes a parking brake switch 18, a vehicle data bus 16, a voltage sensor unit 22, and a motor drive circuit in addition to a memory 21 as a storage unit. 23, the current sensor unit 24 and the like are connected. From the vehicle data bus 16, various state quantities of the vehicle necessary for the control (operation) of the parking brake, that is, various vehicle information can be acquired.

  The vehicle information acquired from the vehicle data bus 16 may be acquired by directly connecting a sensor that detects the information to the parking brake control device 19 (the arithmetic circuit 20 thereof). The arithmetic circuit 20 of the parking brake control device 19 is configured such that an operation request based on the above-described determination logic or ABS control is input from another control device (for example, the control unit 13) connected to the vehicle data bus 16. May be. In this case, the determination of parking brake apply / release and the ABS control by the above-described determination logic can be performed by another control device, for example, the control unit 13, instead of the parking brake control device 19. That is, the control content of the parking brake control device 19 can be integrated into the control unit 13.

  The parking brake control device 19 includes a memory 21 including, for example, a flash memory, a ROM, a RAM, an EEPROM, and the like. In the memory 21, in addition to the aforementioned parking brake apply / release determination logic and ABS control program, a processing program for executing the processing flows shown in FIGS. 4, 5, and 7 to 11, namely, A processing program (FIGS. 4 and 5) for calculating the state (motor rotation amount integrated value) of the electric motors 43B and 43B and a processing program (FIGS. 7 to 11) for releasing the left and right wheels are stored. The memory 21 also stores a relationship (table) between the left-right difference of the motor rotation amount integrated value and the delay time shown in FIG. Further, the memory 21 stores (saves) the states (motor rotation amount integrated values) of the left and right electric motors 43B and 43B so as to be sequentially updated.

  In the embodiment, the parking brake control device 19 is separated from the control unit 13 of the ESC 11, but the parking brake control device 19 may be integrated with the control unit 13. In addition, the parking brake control device 19 controls the two disc brakes 31 and 31 on the left and right, but may be provided for each of the left and right disc brakes 31 and 31. The parking brake control device 19 can also be provided integrally with the disc brake 31.

  As shown in FIG. 3, the parking brake control device 19 includes a voltage sensor unit 22 that detects a voltage from the power line 15, left and right motor drive circuits 23 and 23 that respectively drive the left and right electric motors 43 </ b> B and 43 </ b> B, The left and right current sensor sections 24, 24 for detecting the motor currents of the electric motors 43B, 43B are incorporated. The voltage sensor unit 22, the motor drive circuit 23, and the current sensor unit 24 are connected to the arithmetic circuit 20, respectively.

Thereby, in the arithmetic circuit 20 of the parking brake control device 19, when applying or releasing, the disk rotor 4 and the disk rotor 4 are changed based on the change in the motor current of the electric motors 43B and 43B detected by the current sensor units 24 and 24. determination between contact-separation of the brake pads 33, (determined Apply completed, the determination of the release complete) electric motor 43B, the determination of the stop of the 43B of the drive or the like can be performed.

  By the way, according to Patent Document 1, when applying the parking brake, for example, a voltage drop due to overlapping of starting currents (inrush currents) is suppressed by shifting the starting timing of the electric motors 43B and 43B left and right. be able to. That is, FIG. 14 shows an example of the time change of the current (Current), thrust (Thrust), motor rotation amount integrated value, and parking brake state of the electric motors 43B and 43B according to the comparative example. In FIG. 14, the time change on the left rear wheel 3 side is indicated by a solid line, and the time change on the right rear wheel 3 side is indicated by a broken line.

  For example, if there is an apply request based on the operation of the parking brake switch 18 or the like at the time point (a) in FIG. 14, the current at the left rear wheel 3 rises first at the time point (a), and the time point at (b). The current on the right rear wheel 3 side rises. That is, as shown with “t1” in FIG. 14, when applying the parking brake, the start timing of the electric motors 43B and 43B is shifted left and right, thereby shifting the rising timing of the inrush current left and right. ing. Thereby, a voltage drop can be suppressed.

  Here, in FIG. 14, the current on the right rear wheel 3 side starts increasing at the time point (c), and the current on the left rear wheel 3 side starts increasing at the time point (d). 14 (e), for example, when the current on the left rear wheel 3 side reaches a predetermined value, the apply operation of the disc brake 31 on the left rear wheel 3 side ends. At the time of (f) in FIG. 14, for example, when the current on the right rear wheel 3 side has reached a predetermined value, the apply operation of the disc brake 31 on the right rear wheel 3 side ends.

  In FIG. 14, a left-right difference F <b> 1 is generated in the thrust by the electric motors 43 </ b> B and 43 </ b> B, that is, the force pressing the brake pad 33 against the disc rotor 4 in the state where the apply operation of the left and right disc brakes 31 is completed. Such a left-right difference F1 in thrust, and a left-right difference in inclination (time change) when the current increases during the apply operation are, for example, machines such as the electric motors 43B and 43B and the rotation / linear motion conversion mechanisms 40 and 40. This is caused by the difference in the left and right efficiency and the variation of the components of the disc brake 31.

  On the other hand, as indicated by “t2” in FIG. 14, when the parking brake is released, it is conceivable to shift the start timing from the left and right from the viewpoint of suppressing the voltage drop, as in the case of the apply. That is, when there is a release request based on the operation of the parking brake switch 18 or the like at the time point (g) in FIG. 14, the current on the left rear wheel 3 side rises first at the time point (g), and (h) It is conceivable that the current on the right rear wheel 3 side rises at the point of time. However, at this time, depending on the state of the electric motors 43B and 43B, for example, on the left rear wheel 3 side, the thrust of the disc brake 31 starts to decrease at the time (i) in FIG. 14, and is released at the time (k). While the operation ends, on the right rear wheel 3 side, the thrust starts to decrease at the time point (j) in FIG. 14, and the release operation may end at the time point (l).

  That is, on the left rear wheel 3 side, the time from the start of release until the thrust starts to decrease is the time indicated by “t3” in FIG. 14, whereas on the right rear wheel 3 side, the thrust from the start of release. In some cases, the time until the value begins to decrease is the time indicated by “t4” in FIG. Thus, if the start timing is simply shifted from the viewpoint of suppressing the voltage drop at the start of release, thrust (braking force) is generated by the left and right disc brakes 31 as indicated by “t5” in FIG. There is a possibility that a time difference starts, that is, a time difference between left and right occurs. In this case, the vehicle is shaken in the lateral direction with the time difference between the left and right, and there is a possibility that the passengers (occupants) such as the driver feel uncomfortable and uncomfortable. Note that the left-right time difference t5 shown in FIG. 14 tends to increase as the left-right difference d1 in the motor rotation amount integrated value increases.

  Therefore, in the first embodiment, as shown in FIG. 13, the left and right motors 43 </ b> B and 43 </ b> B have a right and left difference d <b> 1 between the left and right motor rotation amount integrated values. The current supply start timing (control start timing) of the electric motors 43B and 43B is shifted by a predetermined time t6. Specifically, a predetermined value (delay time) t6 minutes corresponding to the left-right difference d1 of the motor rotation amount integrated value obtained based on FIG. 12, the other (right in FIG. 13) than the other electric motor 43B (FIG. 13). The left) delays the start of current supply (release drive) of the electric motor 43B.

  Accordingly, when there is a release request based on the operation of the parking brake switch 18 or the like at the time of (g) in FIG. 13, the current on the right rear wheel 3 side rises first at the time of (g). At the time, the current on the left rear wheel 3 side rises. Then, at the time (i) in FIG. 13, the thrusts of the left and right disc brakes 31 begin to decrease almost simultaneously, the right release operation ends at the time (j), and the left release operation at the time (k). Ends. As a result, as shown by A in FIG. 13, it is possible to reduce the shift in thrust drop, in other words, the time difference between the left and right time until the left and right rear wheels 3 become rotatable.

  In order to perform such a release operation, the parking brake control device 19 includes a state quantity calculation unit corresponding to the processes in FIGS. 4 and 5 and the processes in S42 and S43 in FIG. 7 (the processes in FIGS. 8 and 9). And a control unit corresponding to the processes of S44 and S45 of FIG. 7 (the processes of FIGS. 10 and 11). The state quantity calculation unit calculates the state quantities of the left and right electric motors 43B and 43B during the apply drive. The timing determination unit determines a control start timing for release driving of each of the electric motors 43B and 43B based on the state quantity calculated by the state quantity calculation unit. The control unit supplies current to each of the electric motors 43B and 43B (performs release driving) according to the determination of the timing determination unit.

  First, the state quantity calculation unit corresponding to the processing of FIGS. 4 and 5 will be described with reference to the characteristic line of FIG. The process of FIGS. 4 and 5 is a motor state quantity calculation process performed by the arithmetic circuit 20 of the parking brake control device 19. The control process (calculation process) of FIGS. 4 and 5 is repeatedly executed at a predetermined control cycle, that is, every predetermined time (for example, 10 ms) while the parking brake control device 19 is energized. Here, the control process of FIG. 4 is a process of calculating the state quantity (integrated value of the rotation amount) of the electric motor 43B on the left rear wheel 3 side (hereinafter also referred to as the left electric motor 43B), and the control process of FIG. Is a process of calculating the state quantity (rotation amount integrated value) of the electric motor 43B on the right rear wheel 3 side (hereinafter also referred to as the right electric motor 43B). The control process in FIG. 4 and the control process in FIG. 5 are the same except that the left and right are different. Therefore, the control process in FIG. 4 will be mainly described.

  When the control process of FIG. 4 is started by starting the parking brake control device 19, in S1, the state of the disc brake 31 (hereinafter also referred to as the left disc brake 31) on the left rear wheel 3 side (the parking brake is activated). It is determined whether or not (state) is in an unlocked state. Here, as shown in FIG. 6, the lock state (lock) is a state from the end of apply drive (stop of current supply for apply) to the end of release drive (stop of current supply for release). Correspondingly, the unlocked state (unlock) corresponds to the state from the end of the release drive to the end of the apply drive.

  If it is determined as “YES” in S1, that is, it is in the unlocked state, the process proceeds to S2. If it is determined in S1 that “NO”, that is, it is not in the unlocked state (other than the unlocked state), the process proceeds to S6. In S6, it is determined whether or not the state of the left disc brake 31 (parking brake state) is a locked state. If “YES” in S6, that is, if it is determined to be in the locked state, the process proceeds to S8. On the other hand, if it is determined “NO” in S6, that is, if the left disc brake 31 is not in the locked state, the left disc brake 31 is in an unknown state that is neither locked nor unlocked. In this case, there is a possibility of a failure state such that the electric motors 43B and 43B are stopped unintentionally due to disconnection or the like. Therefore, in this case, calculation is not required, the process proceeds to S7, a clear process for setting the motor rotation amount integrated value to 0 is performed, and the process ends (returns to S1 via a return, and repeats the processes after S1). . Further, if necessary, a fail process such as turning on a fail lamp can be performed.

  On the other hand, in S2, it is determined whether the left electric motor 43B is being applied. If “YES” in S2, that is, if it is determined that the left electric motor 43B is being applied, the process proceeds to S3. On the other hand, if “NO” in S2, that is, if it is determined that the left electric motor 43B is not being applied, it is determined that calculation is not necessary, and the process proceeds to S7. That is, a clear process for setting the motor rotation amount integrated value to 0 is performed in S7, and the process ends (returns to S1 via a return, and repeats the processes after S1).

  In S3, it is determined whether or not the brake pad 33 on the left rear wheel 3 side is in contact with the disc rotor 4, that is, whether the brake pad 33 is in contact with the disc rotor 4 during the apply drive or before contact. . This determination can be made based on the current value detected by the current sensor unit 24. For example, the contact of the brake pad 33 is detected based on whether the current detected by the current sensor unit 24 changes (becomes a predetermined value or more) due to contact with the disc rotor 4. be able to.

  If “YES” in S3, that is, if it is determined that the brake pad 33 on the left rear wheel 3 side is in contact with the disc rotor 4, the process proceeds to S4, and the motor rotation amount of the left electric motor 43B is calculated (calculation). To do. This calculation can be calculated by the following equation (1).

  If the motor rotation amount of the current control cycle is calculated in S4, an addition process is performed in subsequent S5. That is, the motor rotation amount calculated in the current control cycle is added (integrated) to the motor rotation amount integrated value calculated in the previous control cycle. Thereby, in S5, a motor rotation amount integrated value (hereinafter, also referred to as a left integrated value) of the left electric motor 43B is calculated, and the process ends (returns to S1 through a return, and repeats the processes after S1).

  On the other hand, if “NO” is determined in S3, it is considered that the brake pad 33 on the left rear wheel 3 side is not in contact with the disc rotor 4, and thus the process proceeds to S7. That is, a clear process for setting the motor rotation amount integrated value to 0 is performed in S7, and the process ends (returns to S1 via a return, and repeats the processes after S1).

  In S6, “YES”, that is, it is determined that the left disc brake 31 is in the locked state, and when the process proceeds to S8, in S8, it is determined whether or not the left electric motor 43B is in a release drive. If “YES” in S8, that is, if it is determined that the left electric motor 43B is in the release drive, the process proceeds to S9. In S9, the motor rotation amount of the left electric motor 43B is calculated (calculated). This calculation can be calculated by the above equation (1).

  If the motor rotation amount of the current control cycle is calculated in S9, subtraction processing is performed in subsequent S10. That is, the motor rotation amount integrated value of the left electric motor 43B is calculated by subtracting the motor rotation amount calculated in the current control cycle from the motor rotation amount integrated value calculated in the previous control cycle, and the process ends. (Return to S1 via return, and repeat the processing after S1). On the other hand, if it is determined “NO” in S8, that is, if it is determined that the left electric motor 43B is not in the release drive, the process proceeds to S11 and a holding process is performed. That is, the motor rotation amount integrated value calculated in the previous control cycle is held, and the process ends (returns to S1 through a return, and repeats the processes after S1).

  Here, at the time of the first process (first control cycle) at the time of activation of the parking brake control device 19, “NO” is normally set in S1, “YES” in S6, and “NO” in S8. In this case, as the “motor rotation amount integrated value calculated in the previous control cycle” of S11, the initial value read from the memory 21 in the process of S41 of FIG. 7 described later can be used. Also, even if “YES” is determined in S1 during the initial processing at the time of activation, it is normally determined “NO” in S2 and the process proceeds to S7. Further, if “YES” is determined in S6 at the time of activation, the process proceeds to S7. In S7, since the motor rotation amount integrated value becomes 0, the “motor rotation amount integrated value calculated in the previous control cycle” at the time of activation may be any value (the initial value read from the memory 21). Value can be used).

  The control process of FIG. 5 is the same process as the control process of FIG. 4 except that the left and right are different. In this case, the processes in S21 to S31 in FIG. 5 correspond to the processes in S1 to S11 in FIG. Further description of the control process of FIG. 5 is omitted.

  FIG. 6 shows an example of the time change of the current of the electric motor 43B, the thrust based on the driving of the electric motor 43B, the motor rotation amount integrated value, and the parking brake state. The section “A” in FIG. 6 corresponds to the apply drive of the electric motor 43B, the section “S” corresponds to the stop of the electric motor 43B, and the section “R” represents the electric motor 43B. This corresponds to the 43D release drive.

  If there is an apply request based on the operation of the parking brake switch 18 or the like at the time of FIG. 6A, the electric motor 43B starts to apply. When the current value detected by the current sensor unit 24 changes (becomes the contact determination value or more) based on the contact of the brake pad 33 with the disk rotor 4 at the time of FIG. 4 is determined as “YES” in S3 (S23 in FIG. 5). Thereby, the calculation of the motor rotation amount is started by the process of S4 of FIG. 4 (S24 of FIG. 5). That is, the motor rotation amount is added by the processes of S4 and S5 in FIG. 4 (S25 and S26 in FIG. 5), and the motor rotation amount integrated value increases (as a positive state amount) (“u” in FIG. 6). ).

  When the current value detected by the current sensor unit 24 reaches a predetermined value (apply end determination value) at the time of FIG. 6C, the electric motor 43B stops and the apply operation ends. As a result, the locked state is established, and “YES” is determined in S6 of FIG. 4 (S26 of FIG. 5). Furthermore, before the release drive is started, it is determined as “NO” in S8 of FIG. 4 (S28 of FIG. 5), and thus the motor rotation amount integrated value is maintained by the processing of S11 of FIG. 4 (S31 of FIG. 5). The That is, the motor rotation amount integrated value when the apply operation is completed is maintained (section “k” in FIG. 6).

  At the time of FIG. 6D, when there is a release request based on the operation of the parking brake switch 18, the electric motor 43B starts to release. In this case, “YES” is determined in S8 of FIG. 4 (S28 of FIG. 5), and the calculation of the motor rotation amount is started (resumed) by the process of S9 of FIG. 4 (S29 of FIG. 5). That is, the motor rotation amount is subtracted by the processing of S9 and S10 in FIG. 4 (S29 and S30 in FIG. 5), and the motor rotation amount integrated value decreases (as a negative state amount) (“d” in FIG. 6). ).

  When it is determined at the time of FIG. 6 (e) that the release has been completed based on the current value or the like, the electric motor 43B stops and the release operation ends. In this case, “NO” is determined in S2 of FIG. 4 (S22 of FIG. 5), and the motor rotation amount integrated value is cleared (reset) by the process of S7 of FIG. 4 (S27 of FIG. 5). As a result, the motor rotation amount integrated value = 0 (section “z” in FIG. 6).

The processing of FIG. 4 and FIG. 5 is a specific example of the state quantity calculation unit which is a constituent requirement of the present invention. The state quantity calculation unit calculates the state quantity of each of the electric motors 43B and 43B in the left and right wheels (left and right rear wheels 3), specifically, the rotation of the electric motors 43B and 43B while the apply drive is being performed. Calculate the integrated value of the quantity. Here, the parking brake control device 19 includes a detecting portion which brake pads 33 detects that the inter-contact with or apart from the disc rotor 4 (away tangent). In this case, the detection unit, that the brake pads 33 is between abutment or away with respect to the disc rotor 4, current sensor 24 is configured to detect based on the change in current detected.

  In the first embodiment, the detection unit detects that the brake pad 33 on the left rear wheel 3 side has come into contact with the disc rotor 4 as the process of S <b> 3 in FIG. 4. Then, the state quantity calculation unit performs the left rear after the detection unit detects that the brake pad 33 on the left rear wheel 3 side has come into contact with the disk rotor 4 as the processing of S4 and S5 in FIG. An integrated value of the rotation amount of the electric motor 43B on the wheel 3 side is calculated. In addition to this, the detection unit detects that the brake pad 33 on the right rear wheel 3 side is in contact with the disk rotor 4 as the processing of S23 of FIG. Then, the state quantity calculation unit performs the right rear after the detection unit detects that the brake pad 33 on the right rear wheel 3 side has come into contact with the disk rotor 4 as the processing of S24 and S25 in FIG. An integrated value of the rotation amount of the electric motor 43B on the wheel 3 side is calculated.

  Next, a timing determination unit and a control unit corresponding to the process of FIG. 7 will be described. In this case, the processes in S42 and S43 in FIG. 7 (the processes in FIGS. 8 and 9) correspond to the timing determination unit, and the processes in S44 and S45 in FIG. 7 (the processes in FIGS. 10 and 11) correspond to the control unit. To do. That is, the processing of S42 and S43 in FIG. 7 is processing (timing calculation processing) for determining the control start timing of the electric motors 43B and 43B for release driving performed by the arithmetic circuit 20 of the parking brake control device 19. The process of S44 and S45 of FIG. 7 is a release drive process (release drive process) of the electric motors 43B and 43B performed by the arithmetic circuit 20 of the parking brake control device 19. 7 including FIG. 8 to FIG. 11 is repeatedly executed at a predetermined control period, that is, every predetermined time (for example, 10 ms) while the parking brake control device 19 is energized.

  When the parking brake control device 19 is activated and the control process of FIG. 7 is started, the motor rotation amount integrated value is read in S41. That is, in S41, the initial value of the motor rotation amount integrated value is read from the memory 21. This initial value is the motor rotation amount integrated value at that time written (stored) in the memory 21 when the parking brake control device 19 is ended (at the end of control) in S46 of FIG. 7 described later. The motor rotation amount integrated value (initial value) read from the memory 21 in S41 is used in the above-described motor state amount (motor rotation amount integrated value) calculation process (first control cycle) in FIGS. . The process of S41 is performed only when the parking brake control device 19 is activated, that is, during the first process (first control cycle).

  In subsequent S42, a delay time determination process, that is, a process of determining a time for shifting the release timing is performed. This delay time determination process is the process shown in FIG. In S51 of FIG. 8, the state (parking brake state) of both the disc brake 31 on the left rear wheel 3 side and the disc brake 31 on the right rear wheel 3 side (hereinafter also referred to as the left and right disc brakes 31, 31). It is determined whether or not it is locked. If “YES” in S51, that is, if it is determined that both the left and right are locked, the process proceeds to S52. On the other hand, if “NO” in S51, that is, if it is determined that at least one of the left and right is in the unlocked state, the process ends (the process proceeds to S43 in FIG. 7 via a return).

  In S52, it is determined whether both the electric motor 43B on the left rear wheel 3 side and the electric motor 43B on the right rear wheel 3 side (hereinafter also referred to as the left and right electric motors 43B) are stopped. If “YES” in S52, that is, if it is determined that both the left and right sides are stopped, the process proceeds to S53. On the other hand, if “NO” in S52, that is, if it is determined that at least one of the left and right motors is being driven, the process ends (the process proceeds to S43 in FIG. 7 via a return).

  In S53, the absolute value of the left-right difference of the (current) motor rotation amount integrated value calculated in the processing of FIGS. 4 and 5 is calculated. That is, the following formula 2 is calculated (calculated).

  After the left / right difference is calculated in S53, a delay time is set in subsequent S54. Specifically, the delay time corresponding to the left-right difference at that time is obtained based on the relationship (table) between the left-right difference (absolute value) of the motor rotation amount integrated value and the delay time shown in FIG. For example, if the left-right difference is d1 (for example, 10 rotations), the delay time is set to t6 (for example, 30 ms). When the delay time is set based on the table of FIG. 12 in S54, the processing is terminated (proceeds to S43 of FIG. 7 via return).

  In S43 following S42 in FIG. 7, a delay wheel determination process, that is, a process of determining the release operation order (the wheel on the side that delays the drive of the electric motor 43B) is performed. This delay ring determination process is the process shown in FIG. In S61 of FIG. 9, as in S51 of FIG. 8, it is determined whether the left and right disc brakes 31, 31 are in the locked state. In subsequent S62, as in S52 of FIG. 8, it is determined whether or not the left and right electric motors 43B are stopped. If it is determined as “NO” in S61 or S62, the process ends (proceeds to S44 in FIG. 7 via a return).

  In S63, the left / right magnitude relation of the motor rotation amount integrated value is determined. That is, the electric motor 43B having the larger motor rotation amount integrated value is driven (current supply) first, and the smaller electric motor 43B is driven (current supply) later (delayed). For this reason, in S63, it is determined whether the motor rotation amount integrated value of the left electric motor 43B is larger than the motor rotation amount integrated value of the right electric motor 43B.

  If “YES” in S63, that is, if it is determined that the motor rotation amount integrated value of the left electric motor 43B is large, the process proceeds to S64, and the delay wheel, that is, the wheel on the side that drives the electric motor 43B later is set to the right wheel. Set to (Right Rear Wheel 3). On the other hand, if it is determined “NO” in S63, that is, if the motor rotation amount integrated value of the left electric motor 43B is equal to or less than the motor rotation amount integrated value of the right electric motor 43B, the process proceeds to S65, and the delay wheel, The wheel that drives the electric motor 43B later is set to the left wheel (left rear wheel 3). Even when the left and right motor rotation amount integrated values are the same, the reason for setting the delay wheel to the left is to shift the rising timing of the left and right currents (inrush current). If a delay ring is set in S64 or S65, the process is terminated (proceeds to S44 in FIG. 7 via return).

  In S44 following S43 in FIG. 7, release driving of the left electric motor 43B, that is, control start timing shifting processing on the left rear wheel 3 side is performed. This control start timing shifting process (left) is the process shown in FIG. In S71 of FIG. 10, it is determined whether or not the left electric motor 43B is stopped. If “NO” in S71, that is, if the left electric motor 43B is being driven, the process ends (the process proceeds to S45 in FIG. 7 via a return). On the other hand, if “YES” in S71, that is, if the left electric motor 43B is stopped, the process proceeds to S72 to determine whether or not there is a release request (release command) based on the operation of the parking brake switch 18 or the like. If “NO” in S72, that is, if there is no release request, the process ends (the process proceeds to S45 in FIG. 7 via a return). On the other hand, if “YES” in S72, that is, if there is a release request, the process proceeds to S73.

  In S73, it is determined whether or not the delay wheel set in the delay wheel determination process of FIG. 9 is the right wheel. If “YES” in S73, that is, if the delay wheel is the right wheel, the process proceeds to S74, and the release drive on the left rear wheel 3 side is started. That is, a current is supplied to the left electric motor 43B, and the process is terminated (proceeds to S45 in FIG. 7 via a return). On the other hand, if “NO” in S73, that is, if the delay wheel is the left wheel, the process proceeds to S75, and the delay counter is counted up. In subsequent S76, the count of the delay counter (count time) is compared with the delay time set in the delay time determination process of FIG. That is, in S76, it is determined whether or not the count time of the delay counter is equal to or longer than the delay time.

  If “NO” in S76, that is, if it is determined that the count time is less than the delay time, that is, the delay time has not been reached, the process ends (the process proceeds to S45 in FIG. 7 via return). On the other hand, if “YES” is determined in S76, that is, if it is determined that the count time has reached the delay time, the process proceeds to S77, the delay counter is reset to 0 (reset), and the release on the left rear wheel 3 side is continued in S74. Start driving. That is, a current is supplied to the left electric motor 43B, and the process is terminated (proceeds to S45 in FIG. 7 via a return). In this case, the release drive on the left rear wheel 3 side is started after a delay time from the start of the release drive on the right rear wheel 3 side.

  In S45 following S44 in FIG. 7, release driving of the right electric motor 43B, that is, control start timing shifting processing on the right rear wheel 3 side is performed. Thus, in the first embodiment, the control start timing shifting process is performed on each of the left and right sides. The control start timing shifting process (right) is the process shown in FIG. The control process of FIG. 11 is the same process as the control process of FIG. 10 except that the left and right are different. In this case, the processing of S81 to S87 in FIG. 11 corresponds to the processing of S71 to S77 in FIG. The control process of FIG. 11 will not be described further.

  In S46 following S45 in FIG. 7, the motor rotation amount integrated value is written. That is, in S46, the current motor rotation amount integrated value is written (stored) in the memory 21. The process of S46 is performed only at the end of the control of the parking brake control device 19, that is, at the last process (last control cycle). In this case, the control of the parking brake control device 19 ends, for example, after a predetermined time has elapsed since the ignition was turned off. When the process of S46 (substantially the process of S45) ends (returns), the process of FIG. 7 ends. That is, the process returns to S41 (substantially S42) in FIG. 7 via the return in FIG. 7, and the subsequent processing is repeated.

  The processing of S44 and S45 of FIG. 7 (processing of FIG. 10 and FIG. 11) is a specific example of the control unit which is a configuration requirement of the present invention. The control unit reduces the left / right disc brake 31 (left / right difference until the thrust starts to decrease) until the wheel (rear wheel 3) becomes rotatable by the release drive of the left and right wheels. The left and right electric motors 43B and 43B) are controlled. Specifically, the control unit determines the left and right sides based on the state quantity calculated by the state quantity calculation unit (the processes in FIGS. 4 and 5), that is, the integrated value of the rotation amounts of the left and right electric motors 43B and 43B. The electric motors 43B and 43B are controlled so as to reduce the left / right difference in the time until the rear wheel 3 becomes rotatable. In this case, a control part supplies an electric current to each electric motor 43B and 43B according to the determination of a timing determination part.

  The processing of S42 and S43 in FIG. 7 (the processing of FIG. 8 and FIG. 9) is a specific example of the timing determination unit that is a configuration requirement of the present invention. The timing determination unit determines a control start timing for release driving of each of the left and right wheels (left and right rear wheels 3). As the process of S42 in FIG. 7 (process in FIG. 8), the timing determination unit performs the difference between the state quantities of the left and right wheels, that is, the integrated value of the rotation amount of the electric motor 43B on the left rear wheel 3 side and the right rear wheel 3. Based on the difference (absolute value) of the integrated value of the rotation amount of the electric motor 43B on the side, a delay time that is a predetermined value related to time is determined.

  For this purpose, the memory 21 of the parking brake control device 19 has a relationship (table) between the difference between the left and right integrated values (absolute value of the motor rotation amount integrated value left and right difference) and a predetermined value (delay time) shown in FIG. It is remembered. The timing determination unit determines a predetermined value (delay time) based on the relationship shown in FIG.

  And in a control part (processing of S44 and S45), the electric motor 43B of the wheel of one side used as one rear wheel 3 among the left and right rear wheels 3 is changed to the wheel of the other wheel used as the other rear wheel 3. Release drive is started by shifting the control start timing (current supply start timing) by a predetermined value (delay time) from the electric motor 43B. In this case, when the motor rotation amount integrated value of one wheel (rear wheel 3) is larger than the motor rotation amount integrated value of the other wheel (rear wheel 3), the other wheel (rear wheel 3) The release drive of the electric motor 43B is started after being delayed by a predetermined value (delay time) from the release drive of the electric motor 43B of one wheel (rear wheel 3). As a result, as indicated by A in FIG. 13, it is possible to reduce the difference in thrust reduction, in other words, the time difference between the left and right time until the left and right rear wheels 3 become rotatable. The timing determination unit determines which of the left and right rear wheels 3 is the other wheel that delays the start of release driving by the process of S43 in FIG. 7 (the process of FIG. 9). .

  As described above, in the first embodiment, the parking brake control device 19 (the arithmetic circuit 20 thereof) calculates the state quantities of the left and right electric motors 43B and 43B by the processing of FIGS. 4 and 5. And the parking brake control device 19 is in a state in which the left and right rear wheels 3 and 3 can rotate at the time of release driving by the processing of FIGS. 7 to 11 based on the calculated state quantities of the electric motors 43B and 43B. The electric motors 43B and 43B are controlled so as to reduce the difference between the left and right time until. As a result, it is possible to reduce the lateral movement of the vehicle (vibration in the lateral direction) caused by the time difference between the left and right during release. As a result, it is possible to suppress discomfort and discomfort to the passengers (occupants) such as drivers.

  In the first embodiment, the parking brake control device 19 sets the control start timing for the release drive of the left and right electric motors 43B and 43B by the processing of S42 and S43 of FIG. 7 (processing of FIGS. 8 and 9). decide. Then, currents are supplied to the left and right electric motors 43B and 43B according to the control start timing determined by the processing of S44 and S45 of FIG. 7 (processing of FIG. 10 and FIG. 11). Thereby, at the time of release drive, the time difference between the left and right until the left and right rear wheels 3, 3 become rotatable can be reduced.

  In the first embodiment, the parking brake control device 19 performs the difference between the state quantities of the left and right electric motors 43B and 43B (motor rotation amount integrated value) by the process of S42 of FIG. 7 (the processes of S53 and S54 of FIG. 8). The delay time is determined based on the left / right difference. Then, by the processing of S44 and S45 in FIG. 7 (the processing of FIG. 10 and FIG. 11), the electric motor 43B on one side is released by shifting the control start timing by a predetermined value (delay time) from the electric motor 43B on the other side. Start driving. Thereby, at the time of release drive, the time difference between the left and right until the left and right rear wheels 3, 3 become rotatable can be reduced.

  In the first embodiment, the parking brake control device 19 performs an integrated value (motor rotation amount integrated value) of the rotation amounts of the electric motors 43B and 43B as state quantities of the electric motors 43B and 43B by the processing of FIGS. ) Is calculated. If it is determined in S43 of FIG. 7 (S63 of FIG. 9) that the motor rotation amount integrated value on one side is larger than the motor rotation amount integrated value on the other side, the processing of S44 and S45 in FIG. By the process (the processes of FIGS. 10 and 11), the release drive of the other electric motor 43B is delayed by a predetermined value (delay time) from the release drive of the one electric motor 43B and started. Thereby, the difference between the time until the rear wheel 3 on one side becomes rotatable and the time until the rear wheel 3 on the other side becomes rotatable can be reduced.

  According to the first embodiment, the memory 21 stores the relationship between the difference between integrated values (motor rotation amount integrated value left-right difference) and a predetermined value (delay time) shown in FIG. And the parking brake control apparatus 19 determines a predetermined value based on the relationship of FIG. 12 by making a difference into an input by the process of S42 of FIG. 7 (process of S54 of FIG. 8). For this reason, the parking brake control apparatus 19 can determine the time (delay time) which delays the release drive of the other side electric motor 43B, without requiring complicated calculation.

According to the first embodiment, the parking brake control device 19, that the brake pads 33 is between abutment or away with respect to the disc rotor 4 (away contact), the change in current by the current sensor 24 detects Detect based on. Then, the parking brake control device 19 detects the contact between the brake pad 33 and the disk rotor 4 by the process of S3 of FIG. 4 (S23 of FIG. 5), and S4 and S5 of FIG. 4 (S24 and S24 of FIG. 5). By the process of S25), the integrated value after detecting the contact is calculated. Thereby, the parking brake control device 19 does not need to calculate the integrated value before detection of contact, and can reduce the load (load) of the integrated value calculation process.

  Next, FIG. 15 to FIG. 21 show a second embodiment. The feature of the second embodiment is that the switching control is performed to continuously switch the magnitude of the current supplied to the motor at the time of release in accordance with the slope of the road surface where the vehicle is stopped (stopped). It is in. In the second embodiment, the same components as those in the first embodiment are denoted by the same reference numerals, and the description thereof is omitted.

  In the second embodiment, after receiving the release request, the parking brake control device 19 continuously performs energization control for continuously energizing the electric motor 43B and the magnitude of the supply current to the electric motor 43B as necessary. Switching control to switch automatically is performed. Specifically, when the parking brake is released, the parking brake control device 19 performs, for example, switching control (PWM control, duty ratio from 0%) according to the slope of the road surface on which the vehicle is stopped (stopped). And control to be a value smaller than 100%). And the parking brake control apparatus 19 will complete | finish switching control and will perform electricity supply continuation control (control by which a duty ratio will be 100%), for example, if movement start of a vehicle is detected during switching control.

  Thus, when switching control is performed at the time of release, the reduction speed (deceleration speed) of the thrust based on the electric motor 43B (force that presses the brake pad 33 against the disk rotor 4) is slowed (thrust is gradually reduced). )be able to. As a result, when the road surface is inclined more than a predetermined amount downward in the traveling direction of the vehicle, the driver or other passengers feel uncomfortable, that is, the vehicle feels popping out due to a rapid drop in thrust (a sudden start of the vehicle). Can be suppressed.

  Here, FIG. 21 shows an example of the time change of the current (Current) and the thrust (Thrust) of the left and right electric motors 43B, 43B at the time of release. In FIG. 21, the time change on the left rear wheel 3 side is indicated by a solid line, and the time change on the right rear wheel 3 side is indicated by a broken line. “(A) Delay time control” shown on the upper side of FIG. 21 indicates time changes of current and thrust when the delay time control as in the first embodiment is performed. In this case, by delaying the start timing of the current supply of the left electric motor 43B by t7 from the start timing of the current supply of the right electric motor 43B, the time when the thrust starts to decrease can be made substantially the same on the left and right.

  On the other hand, “(B) delay time control + switching control” shown in the center of FIG. 21 represents the current when the delay time control and the switching control described above are performed. The time change of thrust is shown. In this case, the current supply start timing of the left and right electric motors 43B is delayed by t7 by performing the delay time control as in the first embodiment. In addition to this, switching control is started as it is after the inrush currents of the left and right electric motors 43B and 43B converge to gradually reduce the thrust.

  However, in this case, as the drive speed of the electric motor 43B becomes slower due to the switching control, there is a possibility that a difference in left and right occurs in the time when the thrust starts to decrease. That is, as the speed decreases, the left and right disc brakes 31, 31 have a large change in driving speed based on variations, differences in efficiency, and the like, and the left-right difference tends to increase. For this reason, when the electric motors 43B and 43B are started, even if the delay time t7 is provided by the delay time control, the thrust starts to decrease as indicated by “t8” added to “(B)” in FIG. There may be a left-right difference in time. Then, as indicated by “t9” added to “(B)” in FIG. 21, the left-right difference further increases in the thrust reduction section.

  Therefore, in the second embodiment, the switching control start timing control for adjusting the timing for starting the switching control is performed. That is, “(C) delay time control + switching control + start timing control” shown at the bottom of FIG. 21 is a switching in addition to the delay time control as described in the first embodiment and the switching control described above. The time change of an electric current and a thrust at the time of also performing control start timing control is shown.

  In the second embodiment, in addition to the delay time t7, “(C)” in FIG. 21 is attached with “t10”, and the timing for starting the switching control is indicated by the motor rotation amount integrated value at that time. Is adjusted according to (delayed). Specifically, based on the relationship (table) shown in FIG. 20, that is, the relationship between the motor rotation amount integrated value when the motor is stopped in the locked state and the motor rotation amount threshold value at which switching control is to be started, the left electric motor 43B. And the motor rotation amount threshold value of the right electric motor 43B are respectively obtained. Then, the left and right electric motors 43B and 43B start the switching control when the motor rotation amount integrated value being released reaches the motor rotation amount threshold values obtained based on FIG. As a result, it is possible to reduce the deviation in thrust reduction, in other words, the time difference between the left and right time until the left and right rear wheels 3 become rotatable. That is, as shown in FIG. 21 with “(C)” indicated by “t11”, it is possible to suppress the left-right difference in the time when the thrust starts to decrease. Furthermore, as shown by attaching “t12” to “(C)” in FIG. 21, the left-right difference can be suppressed even in the thrust reduction section.

  In order to perform such a release operation, the parking brake control device 19 includes a state quantity calculation unit (the processes of FIGS. 4 and 5) similar to that of the first embodiment. The parking brake control device 19 includes a timing determination unit corresponding to S92 and S93 in FIG. This timing determination unit is the same as the timing determination unit (S42 and S43 in FIG. 7) of the first embodiment, that is, corresponds to the processing in FIGS.

  Furthermore, the parking brake control device 19 includes a switching control start timing determination unit corresponding to S94 and S95 in FIG. 15 (the processes in FIGS. 16 and 17). The switching control start timing determination unit determines the switching control start timing of each of the electric motors 43B and 43B based on the state quantity calculated by the state quantity calculation unit.

  Moreover, the parking brake control apparatus 19 is provided with the delay control part corresponding to the process of S96 and S97 of FIG. 15 as a control part. This delay control unit is the same as the control unit (S44 and S45 in FIG. 7) of the first embodiment, that is, corresponds to the processing in FIGS. 10 and 11.

  In addition, the parking brake control device 19 includes a switching control unit corresponding to the processes of S98 and S99 of FIG. 15 (the processes of FIGS. 18 and 19) as the control unit. A switching control part performs switching control of each electric motor 43B and 43B according to the determination of a switching control start timing determination part.

  Next, the process of FIG. 15 will be described. The process of FIG. 15 is used in the second embodiment instead of the process of FIG. 7 of the first embodiment when performing switching control. The control process of FIG. 15 is repeatedly executed at a predetermined control period, that is, every predetermined time (for example, 10 ms) while the parking brake control device 19 is energized. Here, S91 in FIG. 15 is the same process as S41 in FIG. 7, S92 in FIG. 15 is the same process as S42 in FIG. 7, and S93 in FIG. 15 is the same process as S43 in FIG. S96 in FIG. 15 is the same as S44 in FIG. 7, S97 in FIG. 15 is the same as S45 in FIG. 7, and S100 in FIG. 15 is the same as S46 in FIG. For this reason, description of the processing of S91, S92, S93, S96, S97, and S100 in FIG. 15 is omitted.

  In S94 following S93 of FIG. 15, a switching control start timing determination process, that is, a process of determining the start timing of the switching control of the left electric motor 43B is performed. This switching control start timing determination process (left) is the process shown in FIG. In S101 of FIG. 16, it is determined whether or not the state of the left disc brake 31 (parking brake state) is a locked state. If “YES” in S101, that is, if it is determined to be in the locked state, the process proceeds to S102. On the other hand, if it is determined “NO” in S101, that is, if it is determined to be in the unlocked state, the process ends (the process proceeds to S95 in FIG. 15 via return).

  In S102, it is determined whether or not the left electric motor 43B is stopped. If “NO” in S102, that is, if the left electric motor 43B is being driven, the process ends (proceeds to S95 in FIG. 15 via a return). On the other hand, if “YES” in S102, that is, if the left electric motor 43B is stopped, the process proceeds to S103, and the motor rotation amount threshold value corresponding to the motor rotation amount integrated value at which the left electric motor 43B should start the switching control is set. Set. Specifically, based on the relationship (table) between the motor rotation amount integrated value and the motor rotation amount threshold value shown in FIG. 20, the motor rotation amount threshold value corresponding to the left motor rotation amount integration value at that time (switching control is started). The motor rotation amount integrated value to be obtained) is obtained. In this case, in FIG. 20, three characteristic lines 51, 52, and 53, which are a solid line, a broken line, and an alternate long and short dash line, are set corresponding to the magnitude of the thrust when starting the switching control.

  Assuming that the magnitude of thrust when starting the switching control is large, medium, and small, when starting the switching control with a large thrust, the motor rotation is based on the broken characteristic line 51 of FIG. Set the amount threshold. When switching control is started in a state where the thrust is medium, a motor rotation amount threshold is set based on the solid characteristic line 52 in FIG. When switching control is started in a state where the thrust is small, a motor rotation amount threshold value is set based on the characteristic line 53 of the one-dot chain line in FIG.

  For example, when the left electric motor 43B is stopped in the locked state and the motor rotation amount integrated value is M1 (for example, 50 rotations) and the thrust is medium (for example, 7 kN) and the switching control is started, the motor rotation amount threshold value is M2 (for example, 30 rotations) is set. Note that the magnitude of thrust when starting the switching control, that is, which of the characteristic lines 51, 52, 53 is used depends on the vehicle on which the disc brake 31 is mounted (for example, on the vehicle weight or the like). Can be adjusted (depending on). If the motor rotation amount threshold value is set based on the table of FIG. 20 in S103, the process is terminated (proceeds to S95 of FIG. 15 via return).

  In S95 following S94 in FIG. 15, a switching control start timing determination process for the right electric motor 43B is performed. Thus, in the second embodiment, the switching control start timing is determined for each of the left and right sides. The switching control start timing determination process (right) is the process shown in FIG. The control process of FIG. 17 is the same process as the control process of FIG. 16 except that the left and right are different. In this case, the processing of S111 to S113 in FIG. 17 corresponds to the processing of S101 to S103 in FIG. A further description of the control process of FIG. 17 is omitted.

  In S98 following S97 in FIG. 15, a switching control process during the release drive, that is, a switching control start process for the left electric motor 43B is performed. This switching control start process (left) is the process shown in FIG. In S121 of FIG. 18, it is determined whether or not the left electric motor 43B is in a release drive. If “YES” in S121, that is, if it is determined that the release drive is being performed, the process proceeds to S122. On the other hand, if “NO” in S121, that is, if it is determined that the release drive is not being performed, the process ends (the process proceeds to S99 in FIG. 15 via a return).

  In S122, the motor rotation amount integrated value during the release drive of the left electric motor 43B is compared with the motor rotation amount threshold set in S103 of FIG. That is, it is determined whether the left motor rotation amount integrated value (left integrated value) is equal to or less than the left motor rotation amount threshold value. If “NO” in S103, that is, if it is determined that the left integrated value is larger than the left motor rotation amount threshold value, the process ends (proceeds to S99 in FIG. 15 via return). On the other hand, if “YES” in S103, that is, if it is determined that the left integrated value is equal to or less than the left motor rotation amount threshold value, the process proceeds to S123, and the switching control of the left electric motor 43B is started. That is, the switching control for continuously switching the magnitude of the supply current to the left electric motor 43B is started, and the processing is ended (the process proceeds to S99 in FIG. 15 via return).

  In S99 following S98 in FIG. 15, a switching control start process for the right electric motor 43B is performed. Thus, in the second embodiment, the switching control start process is performed on each of the left and right sides. The switching control start process (right) is the process shown in FIG. The control process of FIG. 19 is the same process as the control process of FIG. 18 except that the left and right are different. In this case, the processing of S131 to S133 in FIG. 19 corresponds to the processing of S121 to S123 in FIG. The control process of FIG. 19 will not be described further.

  The processing in S94 and S95 in FIG. 15 (the processing in FIG. 16 and FIG. 17) is a specific example of the switching control start timing determination unit that is a constituent feature of the present invention. The switching control start timing determination unit determines the switching control start timing of each of the left and right wheels (left and right rear wheels 3). Here, the state quantity (motor rotation amount threshold value) of the left and right electric motors 43B and 43B when performing the apply drive is set as a positive state quantity, and the state quantity (motors) of the left and right electric motors 43B and 43B when performing the release drive. When the rotation amount threshold value is a negative state amount, the switching control start timing determination unit determines the threshold value (motor rotation amount threshold value) based on the positive state amount when the apply drive ends. On the other hand, the processing of S98 and S99 of FIG. 15 (processing of FIG. 18 and FIG. 19) is a specific example of the control unit (switching control unit) which is a constituent element of the present invention. Here, the control unit (switching control unit) performs energization continuation control for continuously energizing the left and right electric motors 43B and 43B, and switching control for continuously switching the supply current to the left and right electric motors 43B and 43B. Switch between and. Furthermore, the control unit (switching control unit) starts switching control when the negative state quantity falls below the threshold during release driving.

  In the second embodiment, the start timing of the switching control is determined by the processing of S94 and S95 as described above, and the switching control is started by the processing of S98 and S99. The basic operation of the second embodiment is described in the first embodiment. There is no particular difference from the form.

  In particular, in the second embodiment, the parking brake control device 19 (the arithmetic circuit 20 thereof) sets the state quantity (motor rotation amount integrated value) of the electric motor 43B when performing the apply drive by the process of S94 (S95). Based on this, a motor rotation amount threshold value is determined. And the parking brake control apparatus 19 is a case where the state quantity (motor rotation amount integrated value) of the electric motor 43B at the time of performing release driving becomes below the motor rotation amount threshold value by the process of S98 (S99). Then, switching control is started. As a result, even when switching control is performed during release driving, as shown in “(C)” of FIG. 21, the time difference between the left and right until the left and right rear wheels 3, 3 become rotatable can be reduced.

  In each of the embodiments described above, the delay wheel determination processing (processing for determining the wheel on the side that delays the drive of the electric motor 43B) by the parking brake control device 19 is performed as shown in FIG. When the values are the same, the case where the left wheel (the left rear wheel 3) is configured as a delay wheel has been described as an example. However, the present invention is not limited to this. For example, as in the modification shown in FIG. 22, when S66 and S67 are provided and the left and right motor rotation amount integrated values are the same, the delay wheel can be any wheel (left and right rear wheels 3, 3). As described above, the reason why one of the left and right wheels is a delay wheel is to shift the rising timing of the current (rush current) of the left and right motors.

  In each of the above-described embodiments, the parking brake control device 19 calculates the motor rotation amount using the above equation 1 as the motor state (motor rotation amount), and calculates the motor rotation amount integrated value obtained by integrating the motor rotation amount. The case where the configuration is used has been described as an example. However, the present invention is not limited to this. For example, the motor state (motor rotation amount) may be directly detected by the rotation sensor (using the detection value of the rotation sensor). Furthermore, it is good also as a structure using the inclination with respect to the time of the electric current of the motor after a braking member contact | abuts to a to-be-brake member as a motor state (motor state quantity).

  In each of the above-described embodiments, the parking brake control device 19 determines the control start timing for the release drive so as to reduce the time difference between the left and right until the left and right rear wheels 3 and 3 become rotatable. (Processing in S42 and S43 in FIG. 7) and a control unit (processing in S44 and S45 in FIG. 7) for supplying current to the left and right electric motors 43B and 43B according to the determination of the timing determination unit The case has been described as an example. However, the present invention is not limited thereto. For example, instead of the timing determination unit, a current value determination unit that determines a current value to be supplied to each motor for release driving of the left and right wheels is further provided, and the control unit determines the current value It is good also as a structure which supplies an electric current to each motor according to the determination of a part.

  In this case, the current value determination unit, based on the difference between the state quantities of the left and right wheels, the first current value supplied to the motor on one wheel and the second current supplied to the motor on the other wheel. The current value is determined, and the control unit supplies the current corresponding to the first current value to the motor on one side of the wheel at the start of release driving, and corresponds to the second current value to the motor on the other side of the wheel. The current can be supplied.

  Further, the state quantity calculation unit calculates an integrated value of the rotation amount of the motor as the state quantity of the motor, and the current value determination unit determines that the integrated value of the rotation amount of the motor of one wheel is the motor of the other wheel. If the rotation amount is larger than the integrated value, the first current value may be determined to be larger than the second current value by a predetermined value.

Moreover, further comprising a detection unit for detecting that the braking member is between the abutting or away against the braked member, state quantity calculation unit, as the quantity of state of the motor, those brake member to be braked member by the detection unit It is good also as a structure which calculates the inclination with respect to the time of the electric current after detecting having contacted.

  In each of the above-described embodiments, the case where the left and right rear wheel side brakes are the disc brakes 31 with the electric parking brake function has been described as an example. However, the present invention is not limited to this, and the left and right front wheel brakes may be disc brakes with an electric parking brake function. Moreover, you may comprise the brake of all the wheels (all four wheels) of a front wheel and a rear wheel by the disc brake with an electric parking brake function.

  In the above-described embodiments, the hydraulic disc brake 31 with the electric parking brake has been described as an example. However, the present invention is not limited to this, and an electric disc brake that does not require supply of hydraulic pressure may be used. Further, the present invention is not limited to the disc brake type brake device, and may be configured as a drum brake type brake device. Further, various brake mechanisms can be employed, such as a drum-in disc brake in which a drum-type electric parking brake is provided on the disc brake, and a configuration in which the parking brake is held by pulling a cable with an electric motor. In this case, for example, when an electric brake mechanism that does not require supply of hydraulic pressure is employed, the control unit applies a braking force to the vehicle as a service brake (based on an apply request by operating a brake pedal or the like) (A motor is driven).

  According to the above embodiment, the control unit reduces the time difference between the left and right until the wheels become rotatable by the release drive of the left and right wheels, based on the state quantities of the left and right motors calculated by the state quantity calculation unit. Control each motor. In other words, the second time indicating the timing shift when the wheels provided in the left and right drive units start rotating than the first predetermined time indicating the time shift between the left and right drive units at the start of release. The predetermined time is shorter. As a result, it is possible to reduce the lateral movement of the vehicle (vibration in the lateral direction) caused by the time difference between the left and right during release. As a result, it is possible to suppress discomfort and discomfort to the passengers (occupants) such as the driver at the time of release.

  According to the embodiment, the control unit further includes a timing determination unit that determines the control start timing for the release drive of the left and right wheels, and the control unit supplies current to each motor according to the determination of the timing determination unit. Yes. For this reason, a control part can reduce the time difference between right and left until a wheel will be in a rotatable state by supplying an electric current to each motor at the control start timing which the timing determination part determined.

  According to the embodiment, the timing determination unit determines a predetermined value related to time based on the difference between the state quantities of the left and right wheels, and the control unit determines a predetermined value for the motor on one wheel from the motor on the other wheel. Accordingly, the release drive is started by shifting the control start timing. For this reason, the control unit can reduce the time difference between the left and right wheels until the wheels become rotatable by starting the release drive by shifting the control start timing by a predetermined value between the left and right wheels.

  According to the embodiment, the state quantity calculation unit calculates an integrated value of the rotation amount of the motor as the state quantity of the motor, and the control unit calculates that the integrated value of the rotation amount of the motor of one wheel is the other wheel. If the motor rotation amount is greater than the integrated value, the release drive of the motor on the other wheel is delayed by a predetermined value from the release drive of the motor on the one wheel, and is started. Thereby, the difference between the time until the wheel on one side becomes rotatable and the time until the wheel on the other side becomes rotatable can be reduced.

  According to the embodiment, the storage unit further stores a relationship between the difference between the integrated values and the predetermined value, and the timing determination unit determines the predetermined value based on the relationship using the difference as an input. For this reason, the timing determination unit can determine the time (delay time) for delaying the release drive of the motor on the other side from the relationship between the difference between the integrated values and the predetermined value without requiring a complicated calculation.

According to an embodiment, further comprising a detection unit for detecting that the braking member is between the abutting or away against the braked member, state quantity calculation unit, the braking member is in contact with the braked member by the detection unit It is set as the structure which calculates the integrated value after detecting this. As a result, the state quantity calculation unit does not need to calculate the integrated value before detection of contact, and can reduce the load (burden) of the integrated value calculation process.

  According to the embodiment, it further includes a current value determining unit that determines a current value to be supplied to each motor for release driving of each of the left and right wheels, and the control unit applies to each motor according to the determination of the current value determining unit. The current is supplied. For this reason, the control unit can reduce the time difference between the left and right until the wheel becomes rotatable by supplying current to each motor at the current value determined by the current value determining unit.

  According to the embodiment, the current value determination unit supplies the first current value supplied to the motor on one side of the wheel and the motor on the other side of the wheel based on the difference between the state quantities of the left and right wheels. The second current value is determined, and the control unit supplies a current corresponding to the first current value to the motor on one side of the wheel at the start of release driving, and the second current to the motor on the other side of the wheel. A current corresponding to the value is supplied. For this reason, the control unit can reduce the time difference between the left and right wheels until the wheel is in a rotatable state by supplying a current corresponding to the first current value and a current corresponding to the first current value in the left and right wheels, respectively. .

  According to the embodiment, the state quantity calculation unit calculates the integrated value of the rotation amount of the motor as the state quantity of the motor, and the current value determination unit determines that the integrated value of the rotation amount of the motor on one side of the wheel If the rotation amount of the wheel motor is larger than the integrated value, the first current value is determined to be larger than the second current value by a predetermined value. Thereby, the difference between the time until the wheel on one side becomes rotatable and the time until the wheel on the other side becomes rotatable can be reduced.

According to an embodiment, it includes a detector for detecting that a braking member is between the abutting or away against the braked member further state quantity calculating unit, as a state amount of the motor, the brake member by the detecting unit to be The inclination with respect to time of the electric current after detecting having contact | abutted to the braking member is calculated. Thereby, the state quantity calculation part can make the inclination with respect to the time of the electric current after detection of contact | abutting be the state quantity of a motor.

  According to the embodiment, the control unit performs switching between the energization continuation control for continuously energizing the motor and the switching control for continuously switching the magnitude of the supply current to the motor. A switching control start timing determination unit for determining a start timing, wherein the state quantity when performing the apply drive is a positive state quantity, and the state quantity when performing the release drive is a negative state quantity, the switching control start timing The determining unit determines a threshold value based on the positive state quantity, and the control unit is configured to start switching control when the negative state quantity falls below the threshold value. Thereby, even when switching control is performed during release driving, the time difference between the left and right until the wheel becomes rotatable can be reduced.

2 Front wheels
3 Rear wheels
4 Disc rotor (braking member)
18 parking brake switch 19 parking brake control device (state quantity calculation unit, control unit, timing determination unit, storage unit, detection unit, current value determination unit, switching control timing determination unit)
21 Memory (storage unit)
24 Current sensor (detection unit)
31 Disc brake (drive unit)
33 Brake pads (braking members)
43B Electric motor (motor)

Claims (13)

In a brake device having a drive unit for applying a drive force for applying braking force to a vehicle by supplying a current to an electric motor and a release drive for releasing the braking force for each of the left and right wheels of the vehicle,
A state quantity calculation unit that calculates a state quantity of each of the motors in the left and right wheels while the apply drive is being performed;
A control unit that controls each of the motors so as to reduce a left-right time difference until the wheels are in a rotatable state by the release drive of each of the left and right wheels based on the state quantity calculated by the state quantity calculation unit; Brake device. A timing determination unit for determining a control start timing for release driving of each of the left and right wheels;
The brake device according to claim 1, wherein the control unit supplies a current to each of the motors according to the determination of the timing determination unit. The timing determination unit determines a predetermined value related to time based on a difference between the state quantities of the left and right wheels,
The brake device according to claim 2, wherein the control unit starts the release drive by shifting the motor of the one wheel from the motor of the other wheel by the predetermined value by shifting the control start timing. The state quantity calculation unit calculates an integrated value of the rotation amount of the motor as the state quantity of the motor,
When the integrated value of the rotation amount of the motor of the one wheel is larger than the integrated value of the rotation amount of the motor of the other wheel, the control unit performs release driving of the motor of the other wheel. The brake device according to claim 3, wherein the brake device is started after being delayed by the predetermined value from the release drive of the motor of the side wheel. A storage unit for storing a relationship between the difference between the integrated values and the predetermined value;
The brake device according to claim 4, wherein the timing determination unit determines the predetermined value based on the relationship with the difference as an input. Further comprising a detection unit for braking member detects that it has between contact or away against the braked member,
6. The brake device according to claim 4, wherein the state quantity calculation unit calculates the integrated value after the detection unit detects that the braking member is in contact with the member to be braked. A current value determining unit for determining a current value to be supplied to each motor for release driving of each of the left and right wheels;
The brake device according to claim 1, wherein the control unit supplies a current to each of the motors according to the determination of the current value determination unit. The current value determining unit is configured to supply a first current value to be supplied to the motor of the one wheel and a motor to be supplied to the motor of the other wheel based on the difference between the state quantities of the left and right wheels. Determine the second current value,
The control unit supplies a current corresponding to the first current value to the one-wheel motor at the start of the release drive, and corresponds to the second current value to the other-wheel motor. The brake device according to claim 7, wherein a current is supplied. The state quantity calculation unit calculates an integrated value of the rotation amount of the motor as the state quantity of the motor,
The current value determination unit determines the first current value as the second current when the integrated value of the rotation amount of the motor of the one wheel is larger than the integrated value of the rotation amount of the motor of the other wheel. The brake device according to claim 8, wherein the brake device is determined to be larger than the value by a predetermined value. Further comprising a detection unit for braking member detects that it has between contact or away against the braked member,
The state quantity calculation unit calculates, as the state quantity of the motor, an inclination of the current with respect to time after the detection unit detects that the braking member is in contact with the member to be braked. The brake device as described in any one of thru | or 9. The control unit performs switching between energization continuation control for continuously energizing the motor and switching control for continuously switching the supply current to the motor,
A switching control start timing determination unit for determining the start timing of the switching control for each of the left and right wheels;
When the state quantity when performing the apply drive is a positive state quantity and the state quantity when performing the release drive is a negative state quantity,
The switching control start timing determination unit determines a threshold based on the positive state quantity,
The brake device according to claim 1, wherein the control unit starts the switching control when the negative state quantity falls below the threshold value. In a brake device comprising a drive unit that is provided on each of the left and right wheels of the vehicle and applies a braking force, and a control device that controls the drive unit,
A first predetermined time indicating a time lag of each of the left and right drive units at the start of release;
The brake device, wherein a second predetermined time indicating a shift in timing at which the wheels provided in each of the left and right drive units start rotating is shorter than the first predetermined time.   The brake device according to claim 12, wherein the control unit calculates the first predetermined time based on a state quantity of a motor of each of the left and right drive units while apply drive is being performed.

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