JP2020015435A - Electric brake device - Google Patents

Abstract

To provide an electric brake device which can improve accuracy for correcting thrust estimation.SOLUTION: A brake mechanism 22 transmits thrust generated by driving an electric motor 22B to a piston 22E for moving a brake pad 22F. An ECU 24 for a rear electric brake controls driving of the electric motor 22B. The ECU 24 for the rear electric brake includes an estimated thrust map correction section 24D as correction means. When the estimated thrust map correction section 24D holds a motor rotation position to a prescribed position by driving the electric motor 22B, the estimated thrust map correction section calculates a correction amount for correcting an estimation value of piston thrust on the basis of the motor rotation position or a current value from a relation of thrust with respect to the current value supplied to the electric motor 22B at the motor rotation position.SELECTED DRAWING: Figure 4

Description

  The present invention relates to an electric brake device for applying a braking force to a vehicle such as an automobile.

  As an electric brake device provided in a vehicle such as an automobile, an electric disc brake that performs “thrust control based on thrust detected by thrust detection means” and “position control based on motor rotation position detected by position detection means” is known. Are known.

JP-A-2003-202042

  In the conventional electric disk brake, the control changes according to the magnitude of the detected thrust. For example, in the high thrust region, the control is performed based on the motor rotation position. Here, in the high thrust region, it is conceivable that the thrust is estimated based on the motor rotational position, and feedback control is performed using the estimated thrust. In this case, if the accuracy of the thrust estimation correction is low, the accuracy of the estimated thrust value may not be sufficiently ensured.

  An object of the present invention is to provide an electric brake device that can improve the accuracy of thrust estimation correction.

  In order to solve the above-described problems, an electric brake device according to the present invention includes a brake mechanism that transmits a thrust generated by driving an electric motor to a piston that moves a brake pad, and a motor rotation position that is determined by driving the electric motor. Calculating a correction amount for correcting an estimated value of a piston thrust based on the motor rotation position or the current value from a relationship of the thrust force with respect to a current value supplied to the electric motor at the motor rotation position when the position is held. Correction means.

  According to the present invention, it is possible to improve the accuracy of the thrust estimation correction.

1 is a schematic diagram illustrating a system configuration of a vehicle equipped with an electric brake device according to an embodiment. FIG. 2 is a schematic diagram showing the electric brake device in FIG. 1 together with a main ECU. It is an explanatory view showing operation of a parking mechanism. It is a control block diagram of an electric brake device. FIG. 4 is a characteristic diagram illustrating an example of a relationship between a thrust and a detection value of a thrust sensor. FIG. 4 is a characteristic diagram illustrating an example of a relationship between a motor rotation position and a thrust. FIG. 4 is a characteristic diagram illustrating an example of a relationship between a motor current and a thrust. 5 is a flowchart showing a parking brake release control process. FIG. 9 is a characteristic diagram illustrating an example of a change over time of a motor rotation position and a motor current at the time of release.

  Hereinafter, an example in which the electric brake device according to the embodiment is mounted on a four-wheel vehicle will be described with reference to the accompanying drawings. Note that each step in the flowchart illustrated in FIG. 8 uses the notation “S” (for example, step 1 = “S1”). In addition, in FIG. 1 and FIG. 2, two hatched lines represent electric lines.

  In FIG. 1, a vehicle 1 is equipped with a brake device 2 (vehicle brake device, brake system) that applies a braking force to wheels (front wheels 3L, 3R, rear wheels 5L, 5R) to brake the vehicle 1. I have. The brake devices 2 correspond to left and right hydraulic brake devices 4 and 4 (front braking mechanisms) provided corresponding to the left front wheel 3L and the right front wheel 3R, and correspond to the left rear wheel 5L and the right rear wheel 5R. Left and right electric brake devices 21 and 21 (rear braking mechanism), a master cylinder 7 that generates hydraulic pressure in response to operation (stepping on) of a brake pedal 6 (operating tool), and a driver (driver) And a pedal stroke sensor 9 for measuring the operation amount of the brake pedal 6.

  The hydraulic brake device 4 is configured by, for example, a hydraulic disc brake, and applies a braking force to the wheels (the front wheels 3L and 3R) by supplying hydraulic pressure (brake hydraulic pressure). The electric brake device 21 is configured by, for example, an electric disk brake, and applies a braking force to wheels (rear wheels 5L and 5R) by driving an electric motor 22B (see FIG. 2). The hydraulic pressure sensor 8 and the pedal stroke sensor 9 are connected to the main ECU 10.

  A hydraulic pressure supply device 11 (hereinafter, referred to as ESC 11) is provided between the master cylinder 7 and the hydraulic brake devices 4 and 4. The ESC 11 includes, for example, a plurality of control valves, a hydraulic pump that pressurizes a brake hydraulic pressure, an electric motor that drives the hydraulic pump, and a hydraulic pressure control reservoir that temporarily stores excess brake fluid (any of them). Are also not shown). Each control valve and the electric motor of the ESC 11 are connected to the front hydraulic pressure device ECU 12. The front hydraulic pressure device ECU 12 includes a microcomputer. The front hydraulic device ECU 12 controls opening and closing of each control valve of the ESC 11 and driving of the electric motor based on a command from the main ECU 10.

  The main ECU 10 includes a microcomputer. The main ECU 10 receives signals from the hydraulic pressure sensor 8 and the pedal stroke sensor 9 and calculates a target braking force for each wheel (four wheels) according to a predetermined control program. The main ECU 10 transmits a braking command to each of the two front wheels to the ECU 12 for the front hydraulic device (that is, the ESC ECU) via the CAN 13 (Controller area network) as a vehicle data bus based on the calculated braking force. I do. The main ECU 10 transmits a braking command (target thrust) for each of the two rear wheels to the rear electric brake ECUs 24 and 24 via the CAN 13 based on the calculated braking force.

  In the vicinity of each of the front wheels 3L, 3R and the rear wheels 5L, 5R, wheel speed sensors 14, 14 for detecting the speeds (wheel speeds) of these wheels 3L, 3R, 5L, 5R are provided. The wheel speed sensors 14, 14 are connected to the main ECU 10. The main ECU 10 can acquire the wheel speeds of the wheels 3L, 3R, 5L, 5R based on the signals from the wheel speed sensors 14, 14.

  A parking brake switch 15 is provided near the driver's seat. The parking brake switch 15 is connected to the main ECU 10. The parking brake switch 15 outputs a signal (operation request signal) corresponding to a parking brake (parking brake) operation request (an application request as a holding request and a release request as a release request) in accordance with a driver's operation instruction. To communicate. The main ECU 10 transmits a parking brake command for each of the two rear wheels to the rear electric brake ECUs 24, 24 based on the operation of the parking brake switch 15 (operation request signal).

  The electric brake device 21 includes a brake mechanism 22, a parking mechanism 23, a main ECU 10, and a rear electric brake ECU 24. In this case, in order to perform position control and thrust control, the electric brake device 21 includes a rotation angle sensor 25 as position detection means for detecting a motor rotation position, and a thrust detection means for detecting thrust (piston thrust). A thrust sensor 26 and a current sensor 27 (refer to FIG. 2) as current detection means for detecting a motor current are provided.

  The brake mechanisms 22 are provided on the left and right wheels of the vehicle 1, that is, on the left rear wheel 5L side and the right rear wheel 5R side. The brake mechanism 22 is configured as an electric brake mechanism. As shown in FIG. 2, for example, the brake mechanism 22 includes a caliper 22A as a cylinder (wheel cylinder), an electric motor 22B as an electric motor (electric actuator), a reduction mechanism 22C, a rotation / linear motion conversion mechanism 22D, It includes a piston 22E as a pressing member, a brake pad 22F as a braking member (pad), and a return spring (not shown). The electric motor 22B is driven (rotated) by the supply of electric power to propel the piston 22E. The electric motor 22B is controlled by the rear electric brake ECU 24 based on a braking command (target thrust) from the main ECU 10. The reduction mechanism 22C reduces the rotation of the electric motor 22B and transmits the rotation to the rotation / linear motion conversion mechanism 22D.

  The rotation / linear motion conversion mechanism 22D converts the rotation of the electric motor 22B transmitted via the speed reduction mechanism 22C into an axial displacement (linear motion displacement) of the piston 22E. The piston 22E is propelled by the drive of the electric motor 22B to move the brake pad 22F. The brake pad 22F is pressed by a disk rotor D as a member to be braked (disk) by a piston 22E. The disk rotor D rotates together with the wheels (rear wheels 5L, 5R). The return spring applies a rotational force in the braking release direction to the rotating member of the rotation / linear motion conversion mechanism 22D when braking is applied. In the brake mechanism 22, the piston 22E is propelled to press the brake pad 22F against the disk rotor D by driving the electric motor 22B. That is, the brake mechanism 22 transmits the thrust generated by driving the electric motor 22B to the piston 22E that moves the brake pad 22F.

  The parking mechanism 23 is provided for each of the brake mechanisms 22, 22, that is, the brake mechanism 22 on the left side (left rear wheel 5L side) and the right side (right rear wheel 5R side). The parking mechanism 23 holds the propulsion state of the piston 22E of the brake mechanism 22. That is, the parking mechanism 23 holds and releases the braking force. For example, as shown in FIG. 3, the parking mechanism 23 includes a ratchet mechanism (lock mechanism) that prevents (locks) rotation by engaging an engaging claw (lever member 23C) with a ratchet wheel (ratchet gear 23B). It is configured. That is, the parking mechanism 23 includes a solenoid 23A, a ratchet gear 23B serving as a ratchet, a lever member 23C serving as an engagement claw, and a compression spring 23D serving as a return spring. The solenoid 23A is driven by power supply (the plunger 23A1 is displaced). The solenoid 23A is controlled by the main ECU 10 and the rear electric brake ECU 24.

  The ratchet gear 23B is integrally fixed to the rotating shaft 22B1 of the electric motor 22B of the brake mechanism 22. On the outer peripheral side of the ratchet gear 23B, a plurality of claws 23B1 that engage with the claws 23C1 of the lever member 23C are provided at equal intervals in the circumferential direction. One end of the lever member 23C is a claw 23C1 that engages with the claw 23B1 of the ratchet gear 23B, and the other end is a connecting portion 23C2 that is connected to the plunger 23A1 of the solenoid 23A. The lever member 23C reciprocates by the solenoid 23A so as to engage with or separate from the pawl 23B1 of the ratchet gear 23B. The compression spring 23D applies an elastic force in a direction in which the claw 23C1 of the lever member 23C is separated from the claw 23B1 of the ratchet gear 23B.

  The rear electric brake ECU 24 is provided corresponding to each of the brake mechanisms 22, 22, that is, the brake mechanism 22 on the left side (left rear wheel 5L side) and the right side (right rear wheel 5R side). ing. The rear electric brake ECU 24 includes a microcomputer. The rear electric brake ECU 24 controls the brake mechanism 22 (electric motor 22B) and the parking mechanism 23 (solenoid 23A) based on a command from the main ECU 10. That is, the rear electric brake ECU 24 constitutes a control device (electric brake control device) that controls the driving of the electric motor 22B based on a braking command (target thrust). In addition, the rear electric brake ECU 24 constitutes a control device (electric parking control device) that controls driving of the parking mechanism 23 (solenoid 23A) based on an operation command. A braking command and an operation command are input from the main ECU 10 to the rear electric brake ECU 24.

  The rotation angle sensor 25 detects the rotation angle (motor rotation angle) of the rotation shaft 22B1 of the electric motor 22B. The rotation angle sensors 25 are provided corresponding to the electric motors 22B of the brake mechanisms 22, respectively, and constitute position detecting means for detecting the rotation position (motor rotation position) of the electric motor 22B. The thrust sensor 26 detects a reaction force to a thrust (pressing force) from the piston 22E to the brake pad 22F. The thrust sensor 26 is provided in each of the brake mechanisms 22, and constitutes a thrust detecting means for detecting a thrust (piston thrust) acting on the piston 22E. The current sensor 27 detects a current (motor current) supplied to the electric motor 22B. The current sensors 27 are provided corresponding to the electric motors 22B of the brake mechanisms 22, respectively, and constitute current detecting means for detecting a motor current of the electric motors 22B. The rotation angle sensor 25, the thrust sensor 26, and the current sensor 27 are connected to the rear electric brake ECU 24.

  The rear electric brake ECU 24 (and the main ECU 10 connected to the rear electric brake ECU 24 via the CAN 13) can acquire the rotation angle of the electric motor 22B based on a signal from the rotation angle sensor 25. The rear electric brake ECU 24 (and the main ECU 10) can acquire the thrust acting on the piston 22E based on the signal from the thrust sensor 26. The rear electric brake ECU 24 (and the main ECU 10) can acquire the motor current supplied to the electric motor 22B based on the signal from the current sensor 27.

  Next, the operation of applying and releasing braking during traveling by the electric brake device 21 will be described. In the following description, an operation when the driver operates the brake pedal 6 will be described as an example. However, the case of the automatic brake is almost the same except that, for example, an automatic brake command is output from the automatic brake ECU (not shown) or the main ECU 10 to the rear electric brake ECU 24.

  For example, when the driver depresses the brake pedal 6 while the vehicle 1 is traveling, the main ECU 10 outputs a command corresponding to the depressing operation of the brake pedal 6 based on a detection signal input from the pedal stroke sensor 9 (for example, The target thrust corresponding to the braking application command is output to the rear electric brake ECU 24. The rear electric brake ECU 24 drives (rotates) the electric motor 22B in the forward direction, that is, in the braking application direction (apply direction), based on a command from the main ECU 10. The rotation of the electric motor 22B is transmitted to the rotation / linear motion conversion mechanism 22D via the reduction mechanism 22C, and the piston 22E advances toward the brake pad 22F.

  As a result, the brake pads 22F, 22F are pressed against the disk rotor D, and a braking force is applied. At this time, the driving of the electric motor 22B is controlled by detection signals from the pedal stroke sensor 9, the rotation angle sensor 25, the thrust sensor 26, and the like, whereby a braking state is established. During such braking, a force in the braking release direction is applied to the rotating member of the rotation / linear motion converting mechanism 22D, and consequently, the rotating shaft 22B1 of the electric motor 22B by a return spring (not shown) provided to the braking mechanism 22. You.

  On the other hand, when the brake pedal 6 is operated to the depressing release side, the main ECU 10 outputs a command corresponding to this operation (for example, a target thrust corresponding to the braking release command) to the rear electric brake ECU 24. The rear electric brake ECU 24 drives (rotates) the electric motor 22B in the reverse direction, that is, in the braking release direction (release direction), based on a command from the main ECU 10. The rotation of the electric motor 22B is transmitted to the rotation / linear motion conversion mechanism 22D via the speed reduction mechanism 22C, and the piston 22E moves backward in a direction away from the brake pad 22F. When the depression of the brake pedal 6 is completely released, the brake pads 22F and 22F are separated from the disk rotor D, and the braking force is released. In the non-braking state in which such braking is released, a return spring (not shown) provided in the brake mechanism 22 returns to the initial state.

  Next, the operations of applying (applying) braking and releasing (releasing) braking by the parking brake will be described. In the following description, the operation when the driver operates the parking brake switch 15 will be described as an example. However, in the case of the automatic parking brake (auto apply, auto release), for example, the automatic operation of the main ECU 10 is performed. This is almost the same except that the commands (auto apply command, auto release command) are output based on the parking brake determination.

  For example, when the driver operates the parking brake switch 15 to the apply side, the main ECU 10 operates (applies) the parking brake. In this case, the main ECU 10 first rotates the electric motor 22B of the brake mechanism 22 to the thrust generation side (apply side: clockwise in FIG. 3) via the rear electric brake ECU 24, and causes the brake pads 22F, 22F to rotate on the disk rotor. D is pressed with a desired force (for example, a force that can keep the vehicle 1 stopped). In this state, the main ECU 10 operates the solenoid 23A of the parking mechanism 23 via the rear electric brake ECU 24. That is, by pulling the plunger 23A1 of the solenoid 23A (displaced upward in FIG. 3), the claw 23C1 of the lever member 23C is pressed against the claw 23B1 of the ratchet gear 23B. At this time, as shown in FIG. 3A, the claw 23C1 of the lever member 23C abuts (interferes) with the top of the claw 23B1 of the ratchet gear 23B, so that the claw 23C1 and the claw 23B1 are engaged. Not always.

  Next, the main ECU 10 rotates the electric motor 22B to the power reduction side (release side: counterclockwise in FIG. 3) via the rear electric brake ECU 24. Thus, even when the claw portion 23C1 and the claw 23B1 are not engaged, as shown in FIG. 3B, the claw portion 23C1 and the claw 23B1 can be reliably engaged. In this state, the energization of the electric motor 22B is stopped, and it is checked whether or not a predetermined thrust (for example, a thrust that can keep the vehicle stopped) has been reached by, for example, the thrust sensor 26. Stop energization. At this time, the ratchet gear 23B (i.e., the rotating shaft 22B1 of the electric motor 22B) applies a rotational force to the reduction side (release side) based on the elastic force of a return spring (not shown) provided to the brake mechanism 22 (see FIG. 3 counterclockwise force). For this reason, even if the energization to the solenoid 23A is stopped, the engaged state between the claw portion 23C1 and the claw 23B1 is maintained as shown in FIG. Thereby, the braking state can be maintained in a state in which the power supply to the electric motor 22B and the solenoid 23A is stopped.

  On the other hand, when the parking brake switch 15 is operated to the release side, the main ECU 10 releases (releases) the operation of the parking brake. In this case, the electric motor 22B is slightly rotated to the thrust generating side (apply side) without energizing the solenoid 23A. Thereby, the engagement between the claw portion 23C1 of the lever member 23C and the claw 23B1 of the ratchet gear 23B is loosened, and the lever member 23C releases the engagement between the claw portion 23C1 and the claw 23B1 by the spring force of the compression spring 23D ( (Clockwise). Then, after confirming whether or not the thrust has changed by the thrust sensor 26, the electric motor 22B is rotated to the power reduction side (release side) to release the braking.

  Next, thrust control and position control by the electric brake device 21 will be described.

  The main ECU 10 obtains a braking force to be generated by the electric brake device 21, that is, a target thrust to be generated on the piston 22E, based on detection data from various sensors (for example, the pedal stroke sensor 9), an automatic brake command, and the like. The main ECU 10 outputs a target thrust as a braking command to the rear electric brake ECU 24. The rear electric brake ECU 24 performs thrust control using the piston thrust detected by the thrust sensor 26 as feedback for the electric motor 22B so that the target thrust is generated by the piston 22E, and the motor detected by the rotation angle sensor 25. Position control using the rotational position as feedback is performed.

  FIG. 4 is a control block diagram of the rear electric brake ECU 24. As shown in FIG. 4, the rear electric brake ECU 24 includes a thrust / estimated thrust feedback control unit 24A, a motor control unit 24B, a thrust estimation map unit 24C, and an estimated thrust map correction unit 24D. The input side of the thrust / estimated thrust feedback control unit 24A is connected to the main ECU 10, the thrust sensor 26, and the thrust estimation map unit 24C. The output side of the thrust / estimated thrust feedback control unit 24A is connected to the motor control unit 24B. The target thrust as a braking command is input from the main ECU 10 to the thrust / estimated thrust feedback control unit 24A. The thrust (piston thrust) detected by the thrust sensor 26 is input to the thrust / estimated thrust feedback control unit 24A. The estimated thrust (estimated piston thrust) is input to the thrust / estimated thrust feedback control unit 24A from the thrust estimation map unit 24C.

  For example, when the thrust / estimated thrust feedback control unit 24A is within the range of the thrust detected by the thrust sensor 26 (low thrust), the “thrust detected by the thrust sensor 26 (measured thrust)” and the “target thrust” And the deviation is determined from the above, and a control amount is output to the motor control unit 24B so as to reduce the deviation. Further, when the thrust / estimated thrust feedback control unit 24A is out of the range of the thrust detected by the thrust sensor 26 (high thrust), the thrust / estimated thrust feedback control unit 24A reads “the thrust estimation map unit based on the motor rotation position detected by the rotation angle sensor 25. The deviation is obtained from the "thrust (estimated thrust) estimated at 24C" and the "target thrust", and a control amount is output to the motor control unit 24B so as to reduce the deviation.

  The input side of the motor control unit 24B is connected to the thrust / estimated thrust feedback control unit 24A, and the output side is connected to the electric motor 22B. A control amount is input to the motor control unit 24B from the thrust / estimated thrust feedback control unit 24A. The motor control unit 24B supplies a current corresponding to the control amount input from the thrust / estimated thrust feedback control unit 24A to the electric motor 22B. As a result, the electric motor 22B is driven, and a target thrust is generated by the piston 22E, so that a braking force corresponding to the target thrust is applied.

  The input side of the thrust estimation map unit 24C is connected to the rotation angle sensor 25 and the estimated thrust map correction unit 24D. The output side of the thrust estimation map section 24C is connected to the thrust / estimated thrust feedback control section 24A. The motor rotation position detected by the rotation angle sensor 25 is input to the thrust estimation map unit 24C. The thrust estimation map unit 24C has a map shown in FIG. 6 described later, that is, a relationship between the motor rotational position and the thrust.

  The thrust estimation map section 24C estimates the thrust from the motor rotation position detected by the rotation angle sensor 25 based on the relationship between the motor rotation position and the thrust (the map shown in FIG. 6). The thrust estimation map unit 24C outputs the estimated thrust to the thrust / estimated thrust feedback control unit 24A. Further, a correction map is input to the thrust estimation map unit 24C from the estimated thrust map correction unit 24D. The thrust estimation map unit 24C can estimate the thrust from the motor rotation position detected by the rotation angle sensor 25 based on the relationship between the motor rotation position and the thrust corrected by the correction map.

  The input side of the estimated thrust map correction unit 24D is connected to the thrust sensor 26, the rotation angle sensor 25, and the current sensor 27. The output side of the estimated thrust map correction unit 24D is connected to the thrust estimation map unit 24C. The estimated thrust map correction unit 24D receives the thrust detected by the thrust sensor 26, the motor rotation position detected by the rotation angle sensor 25, and the motor current detected by the current sensor 27.

  The estimated thrust map correction unit 24D performs correction so that the relationship (map) between the motor rotational position and the thrust used in the thrust estimation map unit 24C can be properly maintained regardless of, for example, aging. For example, within the detection range of the thrust sensor 26 (see FIGS. 5 and 6), the estimated thrust map correction unit 24D uses the characteristic of the thrust detected by the thrust sensor 26 with respect to the motor rotation position to obtain a map of the thrust estimation map unit 24C. Is corrected. That is, the estimated thrust map correction unit 24D corrects the map based on the relationship between the motor rotation position detected by the rotation angle sensor 25 and the piston thrust detected by the thrust sensor 26 within the detection range of the thrust sensor 26.

  On the other hand, the estimated thrust map correction unit 24D calculates the motor rotation position and the motor current value when the motor rotation position is held at a predetermined value, as described later, outside the detection range of the thrust sensor 26 (see FIG. 6). The thrust is estimated, and the map is corrected based on the relationship between the estimated thrust and the motor rotational position. In this case, the estimated thrust map correction unit 24D outputs the corrected map (correction map) to the thrust estimation map unit 24C. Thereby, the estimated thrust map correction unit 24D can estimate the thrust using the correction map.

  By the way, in order to perform the correction with high accuracy, for example, it is conceivable that the thrust is changed by a prescribed operation, and the correction is performed based on a detection value detected when the thrust is changed. However, if a braking force is generated when there is no braking request to perform this detection, for example, when a sudden acceleration request is made, the response of the vehicle may be delayed by the time required to reduce the braking force. There is. In addition, there is a possibility that the accuracy of the correction is deteriorated due to disturbance such as mechanical friction. Therefore, in the embodiment, the thrust estimation is corrected based on the current value of the electric motor 22B when the motor rotation position is held constant during the release of the parking brake, so that the correction is accurately performed within the range of the normal brake operation. Correction can be performed.

  Here, the concept of the method of correcting the thrust map with respect to the motor rotation position will be described with reference to FIGS. FIG. 5 shows an example of the relationship between the thrust and the value detected by the thrust sensor 26. FIG. 6 shows an example of the relationship between the motor rotation position and the thrust. As shown in FIGS. 5 and 6, for the area within the detection range of the thrust sensor 26, the map of FIG. 6 can be corrected by the thrust detected by the thrust sensor 26 with respect to the detection position of the rotation angle sensor 25. is there. Generally, due to the rigidity of the brake pad 22F, the inclination of the map is small in a region where the thrust is relatively low, and the inclination of the map is large in a region where the thrust is relatively high, so that the map becomes substantially linear. Therefore, in a region where the thrust is high, the estimation of the thrust is relatively easy.

  However, when a map in a region with a relatively high thrust is estimated by extrapolation from a map obtained in a region with a relatively low thrust, the error increases as the thrust increases, and the estimation accuracy may decrease. That is, from the relationship between the motor rotational position and the thrust obtained in the region where the thrust is relatively low (for example, point A in FIG. 6), the relationship between the motor rotational position and the thrust in the region where the thrust is higher than this relationship (point A) is obtained. When the relationship (characteristic) is estimated (interpolated), there is a possibility that the deviation (error) from the actual relationship (solid line 51 in FIG. 6) becomes large, as shown by the one-dot chain line 52 or the two-dot chain line 53 in FIG. .

  For this reason, it is desirable to obtain a correctable point at the highest possible thrust and estimate it by interpolation. That is, from the relationship between the motor rotational position and the thrust obtained with the highest possible thrust (for example, point B in FIG. 6), the relationship between the motor rotational position and the thrust in the region of the thrust lower than this relationship (point B) is estimated. (Interpolation) is desirable. In a region where the thrust is relatively high, the relationship (characteristic) between the motor rotation position and the thrust behaves linearly. Therefore, if the correction can be performed at a sufficiently high thrust, even if only one point can be corrected, a sufficient point can be obtained. Accuracy can be ensured.

  On the other hand, in the range of the normal brake (the range of the thrust during driving), there is little opportunity to generate a sufficiently high thrust, and it is difficult to obtain a point where a high thrust can be corrected. For this reason, for example, when the vehicle speed is sufficiently low, the correction may be performed by operating the electric brake device 21 to a relatively high thrust. However, in this case, the brake force is generated when there is no brake request. Therefore, for example, when a sudden acceleration request is made, the braking force must be reduced before the acceleration, and the response of the vehicle may be delayed by the time.

  On the other hand, during the operation of the parking brake, a thrust that is sufficiently larger than the range of the normal brake is generated, so that the timing of the correction is ideal. Moreover, the operation of the parking brake is less likely to hinder the operation of the vehicle. In addition, since the operation of the parking brake is an operation that is normally performed when the vehicle starts and ends, the frequency of correction can be increased, and the accuracy of the map can be kept high. However, since the operation of the parking brake is for a short time, it is considered difficult to accurately perform correction based on a detection value when the thrust is changed, for example. Thus, the embodiment provides a means for accurately estimating the thrust during parking brake.

  That is, FIG. 7 shows an example of the relationship between the motor current and the detected value of the thrust sensor when the thrust increases (when the power is increased) and when the thrust is reduced (when the power is reduced). As shown in FIG. 7, the characteristics of the thrust with respect to the motor current when the electric motor 22B is rotating depend not only on the electric characteristics of the electric motor 22B but also on the variation in the transmission efficiency due to friction and the like of the mechanism of the brake mechanism 22. Change. On the other hand, when the motor rotation position of the electric motor 22B is maintained by the position control based on the motor rotation position, the relationship between the motor current and the thrust generally converges on a straight line with an efficiency of 100% indicated by a broken line 54 in FIG. I do.

  Therefore, when the efficiency is 100%, the motor torque can be estimated from the motor current and the thrust can be calculated using the proportional relationship based on the electric characteristics of the electric motor 22B. The proportional relationship based on the electric characteristics of the electric motor 22B when the efficiency is 100% is determined by the design specification and can be obtained in advance because there is no individual difference. Therefore, by providing an opportunity to maintain the motor rotational position by position control outside the detection range of the thrust sensor 26, it is possible to estimate the thrust from the motor current without considering the effect of efficiency.

  Therefore, in the embodiment, the map is corrected when the motor rotation position is held at a predetermined position (constant position). For this purpose, the rear electric brake ECU 24 includes an estimated thrust map correction unit 24D as correction means. When the electric motor 22B is driven to maintain the motor rotation position at a predetermined position, the estimated thrust map correction unit 24D determines the thrust based on the motor rotation position based on the relationship between the current value supplied to the electric motor 22B at the motor rotation position and the thrust. A correction amount for correcting the estimated value of (piston thrust) is calculated. In this case, when the parking mechanism 23 is released, the electric motor 22B is driven to keep the motor rotational position constant.

  That is, in the embodiment, the motor rotation position is held constant while driving the electric motor 22B to release the parking brake, and the thrust is estimated based on the motor current value at the time of holding the motor rotation position. Is corrected. More specifically, when the parking brake shown in FIG. 3 is released, the electric motor 22B is controlled based on the motor rotation position, and the electric motor 22B is moved to the thrust generating side to release the engagement between the claw portions 23C1 and the claw 23B1. When the claw 23B1 is moved by the distance equal to or longer than the interval, the motor rotation position is held for a certain time in order to confirm that the claw 23B1 has been moved by a desired rotation. At this time, the thrust is estimated from the held motor current value, and the thrust for the motor rotational position is corrected. The predetermined position of the motor rotation position (the position where the motor rotation position is held constant) may be a motor rotation position having a high thrust so that the relationship (map) between the thrust and the motor rotation position can be accurately corrected. preferable. For example, the predetermined position corresponds to a thrust within a range of 60 to 100% (more preferably, 75 to 90%) of the maximum thrust that can be generated by driving the electric motor 22B, such as point B in FIG. Motor rotation position.

  In order to perform such a correction, the memory of the rear electric brake ECU 24 stores a processing program for executing the processing flow shown in FIG. 8, that is, a processing program used for the control processing for releasing the parking brake. I have. Thus, control processing performed by the arithmetic circuit of the main ECU 10 will be described with reference to FIG. Note that the control process of FIG. 8 is repeatedly executed at a predetermined control cycle (for example, 10 ms) while power is supplied to the rear electric brake ECU 24, for example.

  For example, when the control process of FIG. 8 is started by the start of energization of the rear electric brake ECU 24, in S1, it is determined whether or not there is a release request (release request) of the parking brake (parking brake). That is, in S1, it is determined whether a release command (release request) based on the operation of the parking brake switch 15 or a release command (release request) based on the auto release determination is input from the main ECU 10 to the rear electric brake ECU 24. judge.

  If "NO" in S1, that is, if it is determined that there is no cancellation request, the process returns to S1 and the processes after S1 are repeated. On the other hand, if "YES" in S1, that is, if it is determined that there is a release request, the process proceeds to S2. In S2, the position of the electric motor 22B is controlled to the disengagement position. That is, in S2, the motor rotation position rotated to the thrust generating side (apply side) by a specified amount with respect to the motor rotation position in a state where the ratchet gear 23B of the parking mechanism 23 and the lever member 23C are engaged is set as a command. Then, the position of the electric motor 22B is controlled. Here, the specified amount is equal to or larger than the interval between the claws 23B1 of the ratchet gear 23B in FIG. In S2, when the drive of the electric motor 22B to the thrust generating side is started based on the motor rotation position command, the process proceeds to S3.

  In S3, it is determined whether or not the vehicle has reached the disengagement position. That is, in S3, it is determined that the motor rotation position does not change for the specified time near the motor rotation position command. If "NO" in S3, that is, if it is determined that the motor rotational position changes, the process returns to S3 and the processes after S3 are repeated. On the other hand, if "YES" in S3, that is, if it is determined that the motor rotational position does not change for the specified time, the process proceeds to S4.

  In S4, a thrust estimation correction process is performed. That is, in S4, since the motor rotational position is held by determining "YES" in S3, the thrust is estimated from the motor current value. That is, the thrust is estimated from the motor current value based on the map shown in FIG. 7 (broken line 54 corresponding to the relationship between the motor current and the thrust obtained at the efficiency of 100% obtained in advance). Thereby, the relationship between the “motor rotation position” and the “thrust”, which are the correction points in the map of FIG. 6, can be obtained. The map shown in FIG. 7, that is, the relationship between the motor current and the thrust at an efficiency of 100% is obtained in advance and stored in the memory of the rear electric brake ECU 24.

  Through the processing in S4, the estimated thrust map correction unit 24D of the rear electric brake ECU 24 can obtain a correction amount for correcting the thrust. Then, the estimated thrust map correction unit 24D outputs a correction map corresponding to the correction amount to the thrust estimation map unit 24C. The thrust estimation map unit 24C can accurately estimate the thrust from the motor rotation position using the correction map.

  When the correction processing is performed in S4, that is, when the correction point is obtained by estimating the thrust from the motor current, the process proceeds to S5. In S5, the electric motor 22B is rotated to the power reduction side (release side) to release the braking. Specifically, the electric motor 22B is driven to the reduced force side until the target thrust corresponding to the operation amount of the brake pedal 6 at that time (the target thrust is 0 kN when the brake pedal 6 is not operated), and the process returns. . That is, the process returns to the start via the return, and the processing after S1 is repeated.

  FIG. 9 shows a time change of the motor rotation position and the motor current when the parking brake is released. If there is a parking brake release request at time t1 in FIG. 9, the electric motor 22B is driven to the thrust generating side from time t1 to time t2 in FIG. That is, by the processing of S2 in FIG. 8, the position control is performed using the motor rotation position moved to the thrust generating side by the specified amount with respect to the motor rotation position in the state where the parking mechanism 23 is engaged as a command. Then, at time t2 in FIG. 9, it is confirmed whether or not the electric motor 22B has been driven to the command position. That is, in order to confirm that the engagement of the parking mechanism 23 has been released by the processing of S3 in FIG. 8, it is determined that the motor rotation position does not change for a prescribed time near the command. When it is determined that the motor has reached the command position at time t3 in FIG. 9, the motor rotational position is held, so that the thrust is estimated from the current value by the correction processing in S4, and the map correction of the estimated thrust is performed. Do. After performing the correction processing at the time point t3 in FIG. 9, the electric motor 22B is rotated to the power reduction side to release the braking. In FIG. 9, the control is performed assuming that the brake pedal 6 is not operated (the target thrust is zero (0) kN). However, if the target thrust is determined by pedal operation or the like, the force is reduced to that value. Will be.

  As described above, according to the embodiment, when the electric motor 22B is driven to maintain the motor rotational position at the predetermined position, the estimated value of the thrust (piston thrust) is determined from the relationship between the current value (motor current value) and the thrust. A correction amount to be corrected is calculated. In this case, as shown in FIG. 7, when the motor rotation position is held at a predetermined position, the electric motor is controlled using the proportional relationship based on the electric characteristics of the electric motor 22B without considering the effect of the efficiency. The thrust can be estimated from the current value of 22B. Therefore, even if the thrust sensor 26 does not detect the thrust (outside the detection range of the thrust sensor 26), the correction amount for correcting the estimated value of the thrust (piston thrust) can be obtained with high accuracy, and the accuracy of the thrust estimation correction can be improved. Can be improved. As a result, the thrust can be accurately estimated.

  In addition, according to the embodiment, when the parking mechanism 23 is released, the thrust estimation is corrected by keeping the motor rotational position constant. For this reason, the correction can be performed accurately within the range of the normal brake operation. That is, since the correction can be performed with a high thrust at the time of releasing the parking mechanism 23, the accuracy of the correction can be improved. Moreover, since the frequency of correction can be increased, it is possible to accurately estimate the piston thrust from this aspect as well.

  In the embodiment, when the parking mechanism 23 is released, the motor rotation position is held at a predetermined position, and a correction amount for correcting the estimated value of the thrust (piston thrust) at this time is calculated. And explained. However, the present invention is not limited to this. For example, when the parking mechanism 23 is held (applied), the motor rotation position is held at a predetermined position while a desired thrust is generated, and the thrust (piston thrust) at this time is estimated. The correction amount for correcting the value may be calculated. That is, when the parking brake is operated, it is easy to hold the motor rotational position and obtain an opportunity to make a correction. Therefore, it is preferable to calculate the correction amount by using this.

  Alternatively, the correction amount may be calculated when the motor rotation position is held during the release of the parking mechanism 23 so as to simultaneously reduce the parking brake forces of the left and right wheels. Further, regardless of the operation of the parking mechanism, that is, after the parking mechanism is in the holding state (applied state) or after the parking mechanism is in the released state (release state), the motor rotation position is held constant. A correction amount for correcting the estimated value of the thrust (piston thrust) at that time may be calculated.

  In the embodiment, when the motor rotation position is held at a predetermined position by driving the electric motor 22B, the estimated value of the piston thrust based on the motor rotation position is obtained from the relationship of the thrust to the current value supplied to the electric motor 22B at the motor rotation position. The case where the correction amount for correcting the correction is calculated has been described as an example. However, the present invention is not limited to this. For example, when the motor rotation position is held at a predetermined position by driving the electric motor, the thrust relationship between the current value supplied to the electric motor at the motor rotation position and the thrust force of the piston based on the current value is obtained. It may be configured to calculate a correction amount for correcting the estimated value. That is, when the motor rotation position is held at a predetermined position by driving the electric motor, the estimated value of the piston thrust based on the motor rotation position or the current value is obtained from the relationship of the thrust to the current value supplied to the electric motor at the motor rotation position. The correction amount to be corrected may be calculated.

  In the embodiment, the "main ECU 10", the "rear electric brake ECU 24 for the left rear wheel 5L", and the "rear electric brake ECU 24 for the right rear wheel 5R" are separate ECUs, and these three ECUs are The case where the connection is made by the CAN 13 which is a vehicle data bus has been described as an example. That is, the case where the three ECUs of the main ECU 10 and the left and right rear electric brake ECUs 24 and 24 are configured as control devices (electric brake control devices) for the electric brake devices 21 and 21 has been described as an example. However, the present invention is not limited to this. For example, the main ECU and the rear electric brake ECU may be configured by one ECU. That is, the control device for controlling the left and right electric motors and the left and right parking mechanisms (solenoids) may be configured by one ECU.

  In the embodiment, the case where the brake mechanism 22 and the rear electric brake ECU 24 are configured as one unit (assembly) by attaching the rear electric brake ECU 24 to the brake mechanism 22 has been described as an example. However, the invention is not limited to this. For example, the brake mechanism and the rear electric brake ECU may be arranged separately. In this case, the electric brake ECU (rear electric brake ECU) may be provided separately on the left side (left rear wheel side) and the right side (right rear wheel side), or may be provided on the left side (left rear wheel side) and the right side. (The right rear wheel side) may be configured as one (common) electric brake ECU (rear electric brake ECU).

  In the embodiment, the case where the front wheels 3L and 3R are hydraulic brake devices 4 and 4 and the rear wheels 5L and 5R are electric brake devices 21 and 21 has been described as an example. However, the invention is not limited to this. For example, the front wheel side may be an electric brake device, and the rear wheel side may be a hydraulic brake device.

  In the embodiment, the case where the left and right electric brake devices 21 and 21 on the rear wheel side are provided with a parking mechanism has been described as an example. However, the present invention is not limited to this. For example, an electric brake device having a parking mechanism may be arranged on each of the left front wheel side and the right front wheel side. Further, electric brake devices provided with a parking mechanism may be arranged on each of four wheels, that is, left and right front wheels and left and right rear wheels. In other words, the electric brake devices may be arranged on each of the four wheels, that is, the left and right front wheels and the left and right rear wheels, and the parking mechanisms may be provided on the left and right front wheels and / or the left and right rear wheel electric brake devices. In short, the electric brake devices of at least a pair of left and right wheels among the wheels of the vehicle can be configured by the electric brake devices including the parking mechanism.

  As the electric brake device based on the above-described embodiment, for example, the following embodiments can be considered.

  (1). As a first aspect, a brake mechanism for transmitting a thrust generated by driving an electric motor to a piston for moving a brake pad, and a motor rotating position maintained at a predetermined position by driving the electric motor, Correction means for calculating a correction amount for correcting an estimated value of a piston thrust based on the motor rotation position or the current value from a relationship of the thrust with a current value supplied to the electric motor at the rotation position.

  According to the first aspect, when the electric motor is driven to maintain the motor rotational position at the predetermined position, the correction amount for correcting the estimated value of the piston thrust from the relation of the thrust to the current value is calculated. In this case, when the motor rotation position is held at the predetermined position, the thrust is estimated from the current value of the electric motor using a proportional relationship based on the electric characteristics of the electric motor without considering the effect of the efficiency. be able to. For this reason, even when the thrust sensor does not detect (even outside the detection range of the thrust sensor), the correction amount for correcting the estimated value of the piston thrust can be accurately obtained, and the accuracy of the thrust estimation correction can be improved. it can. As a result, the piston thrust can be accurately estimated.

  (2). As a second aspect, in the first aspect, a parking mechanism for holding and releasing a braking force is provided, and when the parking mechanism is released, the motor rotation position is kept constant by driving an electric motor. .

  According to the second aspect, when the parking mechanism is released, the thrust estimation is corrected by keeping the motor rotational position constant. For this reason, the correction can be performed accurately within the range of the normal brake operation. That is, since the correction can be performed with a high thrust when the parking mechanism is released, the accuracy of the correction can be improved. Moreover, since the frequency of correction can be increased, it is possible to accurately estimate the piston thrust from this aspect as well.

DESCRIPTION OF SYMBOLS 1 Vehicle 2 Brake device 5L, 5R Rear wheel (wheel)
10 Main ECU
Reference Signs List 21 electric brake device 22 brake mechanism 22B electric motor 22E piston 22F brake pad 23 parking mechanism 24 rear electric brake ECU (correction means)
24D estimated thrust map correction unit (correction means)
D Disk rotor (disk)

Claims (2)

A brake mechanism that transmits a thrust generated by driving an electric motor to a piston that moves a brake pad;
When a motor rotation position is held at a predetermined position by driving the electric motor, a piston thrust based on the motor rotation position or the current value is obtained from a relationship of the thrust to a current value supplied to the electric motor at the motor rotation position. And a correction unit for calculating a correction amount for correcting the estimated value. In claim 1,
It has a parking mechanism to hold and release the braking force,
An electric brake device, wherein when the parking mechanism is released, the motor rotation position is kept constant by driving an electric motor.

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