JP2011073659A - Brake control device for vehicle - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a brake control device for a vehicle, enabling contribution to further stabilizing the behavior of the vehicle by adjusting the operation mode of a first solenoid valve during controlling an anti-lock brake. <P>SOLUTION: During ABS control, an ECU acquires actual WC pressure Pwc_r in a wheel cylinder in accordance with a detection signal from a pressure sensor and acquires estimated WC pressure Pwc_e in the wheel cylinder in accordance with the drive modes of a pressure intensifying valve and a pressure reducing valve. The ECU adjusts a command current valve Id to be supplied to the pressure intensifying valve (a eighth timing t18-a ninth timing t19) so that the actual WC pressure Pwc_r approximates the estimated WC pressure Pwc_e when there is a difference between the actual WC pressure Pwc_r and the estimated WC pressure Pwc_e. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a vehicle braking control device for controlling a braking force applied to wheels mounted on a vehicle.

  In general, the vehicle is subjected to anti-lock brake control (also referred to as “ABS control”) for suppressing the lock of the wheels and ensuring the steering performance of the vehicle at the time of vehicle braking based on the brake operation by the driver. A braking control device for controlling the brake actuator is provided. The brake actuator includes a master cylinder that generates a master cylinder pressure corresponding to a brake operation by a driver, a wheel cylinder that is provided for each wheel, and that applies a braking force corresponding to the wheel cylinder pressure generated inside the wheel to the wheel. It has a route that allows communication. In this path, when increasing the wheel cylinder pressure (also referred to as “WC pressure”) in the wheel cylinder, the pressure increasing valve (normally open type electromagnetic valve) that is opened when the pressure is increased, and when reducing the WC pressure, A pressure reducing valve (normally closed electromagnetic valve) that is in an open state is provided.

  Then, when the ABS control start condition is satisfied during the brake operation by the driver, the braking control device executes the ABS control. Specifically, in order to reduce the WC pressure in the wheel cylinder, the braking control device performs pressure reduction control that closes the pressure increasing valve and opens the pressure reducing valve. Thereafter, in order to gradually increase the WC pressure in the wheel cylinder, the braking control device performs linear pressure increase control in which the pressure reducing valve is closed and the pressure increasing valve is gradually opened from the closed state. At this time, the command current value supplied to the pressure increasing valve is set based on a predetermined characteristic map. The predetermined characteristic map is an estimated value (also referred to as “differential pressure estimated value”) of a differential pressure between the WC pressure in the wheel cylinder and the master cylinder pressure (also referred to as “MC pressure”) in the master cylinder. And a command current value supplied to the pressure increasing valve (see Patent Document 1).

JP 2007-91051 A

  By the way, the pressure increasing valve is mass-produced in a factory or the like. Therefore, there is naturally variation in the characteristics of each pressure increasing valve. In addition, the characteristics of the pressure increasing valve may change when its temperature changes or when it is used for a long time. Furthermore, the characteristics (particularly viscosity) of the brake fluid used in the brake actuator may change with the passage of time or the change of the fluid temperature. Therefore, even when the command current value for the pressure increasing valve is set based on the predetermined characteristic map during the pressure increasing control during the ABS control, the estimated differential pressure, the WC pressure in the wheel cylinder, and the MC pressure in the master cylinder The actual pressure difference may deviate. Further, if the brake operation amount is changed during the ABS control, the MC pressure in the master cylinder will change, and the estimated differential pressure may deviate from the actual differential pressure. In such a case, the braking force applied to the wheel cannot be adjusted appropriately.

  As a method for solving such a problem, Patent Document 1 discloses an estimation of a differential pressure between the WC pressure in the wheel cylinder and the MC pressure in the master cylinder based on the time from when the brake operation is started to when the ABS control is started. A method for correcting the value is described. A method for correcting the estimated differential pressure when a change in the brake operation amount during the ABS control is detected is also described. However, since the WC pressure in the wheel cylinder and the MC pressure in the master cylinder are both estimated values, there is room for improvement in the correction accuracy of the differential pressure estimated value.

  The present invention has been made in view of such circumstances. An object of the present invention is to provide a vehicle braking control device that can contribute to further stabilization of the behavior of the vehicle by adjusting the operation mode of the first electromagnetic valve during the antilock brake control.

  In order to achieve the above object, the invention according to claim 1 of the vehicle braking control device is to apply a braking force to the wheels (FW, RW) when a start condition of the antilock brake control is satisfied. Master cylinder corresponding to the brake operation so that the pressure reduction control for reducing the wheel cylinder pressure (Pwc_r) in the wheel cylinders (17f, 17r) and the pressure increase control for gradually increasing the wheel cylinder pressure (Pwc_r) are repeated. A first solenoid valve (24f, 24r) disposed between a master cylinder (20f, 20r) that generates pressure (Pmc) and the wheel cylinder (17f, 17r) and opened during the pressure increase control; In the vehicle braking control device that controls the second solenoid valve (25f, 25r) that opens during the pressure reduction control, the vehicle includes the hoisting device. Pressure detecting means (SE4, SE5) for detecting the wheel cylinder pressure (Pwc_r) in the cylinder (17f, 17r) is provided, and the estimated wheel cylinder pressure (Pwc_e) in the wheel cylinder (17f, 17r) is provided. The wheel cylinder pressure (Pwc_r) in the wheel cylinder (17f, 17r) is acquired based on the detection signal from the wheel cylinder pressure estimation means (16, S27) and the pressure detection means (SE4, SE5). Wheel cylinder pressure acquisition means (16, S26) and wheel cylinder pressure (Pwc_r) acquired by the wheel cylinder pressure acquisition means (16, S26) were acquired by the wheel cylinder pressure estimation means (16, S27). Approach the wheel cylinder pressure estimate (Pwc_e) , And summarized in that comprises the first solenoid valve (24f, 24r) and electromagnetic valve control means for adjusting the opening operation (16, S34, S35, S36, S41) of, a.

  According to the above configuration, the estimated value of the wheel cylinder pressure in the wheel cylinder is estimated, and the wheel cylinder pressure in the wheel cylinder is detected based on the detection signal from the pressure detection means. During the antilock brake control, the operation mode of the first electromagnetic valve is adjusted so that the wheel cylinder pressure approaches the estimated wheel cylinder pressure value. Therefore, the braking force on the wheel is appropriately adjusted during the antilock brake control. Therefore, it is possible to contribute to further stabilization of the behavior of the vehicle by adjusting the operation mode of the first electromagnetic valve during the antilock brake control.

  According to a second aspect of the present invention, in the vehicle braking control device according to the first aspect, the electromagnetic valve control means (16, S34, S35, S36, S41) includes the wheel cylinder pressure estimating means (16, S27). The absolute value of the pressure difference (Pwc_sub) between the wheel cylinder pressure estimated value (Pwc_e) acquired by the above-mentioned wheel cylinder pressure (Pwc_r) acquired by the wheel cylinder pressure acquisition means (16, S26) is preset. When the pressure difference threshold value (KPwc1, KPwc2) is equal to or greater than, the opening operation of the first solenoid valve (24f, 24r) is performed so that the wheel cylinder pressure (Pwc_r) approaches the estimated wheel cylinder pressure value (Pwc_e). The gist is to adjust.

  According to the above configuration, when the pressure difference between the wheel cylinder pressure and the estimated value of the wheel cylinder pressure is greater than or equal to the pressure difference threshold value during anti-lock brake control, a braking force having an appropriate magnitude is not applied to the wheel. It is judged. Then, the first solenoid valve is driven so that the wheel cylinder pressure approaches the estimated wheel cylinder pressure value. As a result, it is possible to execute appropriate braking control on the wheels.

  According to a third aspect of the present invention, in the vehicle braking control device according to the second aspect, the electromagnetic valve control means (16, S34, S35, S36, S41) includes the wheel cylinder pressure estimating means (16, S27). The absolute value of the pressure difference (Pwc_sub) between the wheel cylinder pressure estimated value (Pwc_e) acquired by the above-mentioned wheel cylinder pressure (Pwc_r) acquired by the wheel cylinder pressure acquisition means (16, S26) is preset. When the pressure difference threshold (KPwc1, KPwc2) is greater than or equal to the pressure difference threshold (Pwc_sub), the gist is to adjust the command current value (Id) supplied to the first electromagnetic valve (24f, 24r) according to the pressure difference (Pwc_sub). To do.

  According to the above configuration, when the pressure difference between the wheel cylinder pressure and the estimated wheel cylinder pressure value is greater than or equal to the pressure difference threshold value during the antilock brake control, the command current value supplied to the first solenoid valve is the pressure difference Will be adjusted according to. Therefore, after the command current value is corrected, the braking force on the wheels is appropriately controlled, and as a result, it is possible to contribute to the improvement of the stability of the behavior of the vehicle during the antilock brake control.

  According to a fourth aspect of the present invention, in the vehicle braking control apparatus according to any one of the first to third aspects, the wheel cylinder pressure estimating means (16, S27) and the wheel cylinder pressure acquiring means. (16, S26) is a wheel cylinder pressure estimated value (Pwc_e) at the time of switching from the pressure increase control to the pressure reduction control or the time of switching from the pressure reduction control to the pressure increase control during the antilock brake control; The gist is that each wheel cylinder pressure (Pwc_r) can be acquired.

  According to the said structure, the acquisition timing of a wheel cylinder pressure and a wheel cylinder pressure estimated value is unified. Therefore, it is possible to appropriately adjust the operation mode of the first solenoid valve as compared with the case where the acquisition timing of the wheel cylinder pressure and the wheel cylinder pressure estimated value is different each time.

  According to a fifth aspect of the present invention, in the vehicle braking control device according to the second or third aspect, the wheel cylinder pressure estimating means (16, S27) and the wheel cylinder pressure acquiring means (16, S26) are In the antilock brake control, the estimated wheel cylinder pressure (Pwc_e) and the wheel cylinder pressure (Pwc_r) at the time of switching from the pressure increasing control to the pressure reducing control or the time of switching from the pressure reducing control to the pressure increasing control. Each of the electromagnetic valve control means (16, S34, S35, S36, S41) and the wheel cylinder pressure estimated value (Pwc_e) obtained by the wheel cylinder pressure estimating means (16, S27) and the Wheel cylinder pressure (Pwc) acquired by the wheel cylinder pressure acquisition means (16, S26) r) when the absolute value of the pressure difference (Pwc_sub) exceeds the pressure difference threshold (KPwc1, KPwc2) for a predetermined number of times (KC1, KC2), the wheel cylinder pressure (Pwc_r) is The gist is to adjust the opening operation of the first solenoid valves (24f, 24r) so as to approach the estimated pressure value (Pwc_e).

  The detection signal from the pressure detection means may include a noise component unnecessarily. Therefore, even if it is detected only once that the pressure difference between the wheel cylinder pressure and the wheel cylinder pressure estimated value is equal to or greater than the pressure difference threshold value, the wheel cylinder pressure estimated value does not necessarily deviate from the wheel cylinder pressure. Not exclusively. That is, there is a possibility of erroneous determination. Therefore, in the present invention, when it is continuously detected a predetermined number of times that the pressure difference between the wheel cylinder pressure and the wheel cylinder pressure estimated value is equal to or greater than the pressure difference threshold value, the wheel cylinder pressure estimated value deviates from the wheel cylinder pressure. The operation mode of the first solenoid valve is adjusted. Therefore, the mistake of the braking control with respect to the wheel resulting from the erroneous determination is suppressed.

The block diagram of the brake device of the vehicle in this embodiment. The map which shows the relationship between a differential pressure estimated value and command electric current value. The flowchart explaining the braking control processing routine in this embodiment. The flowchart explaining the ABS control processing routine (first half part). The flowchart explaining the ABS control processing routine (second half part). (A), (b), (c), (d), and (e) show changes in vehicle speed, wheel speed, estimated MC pressure, actual WC pressure, estimated WC pressure, estimated differential pressure value, and command current value during ABS control. Timing chart. (A), (b), and (c) are timing charts showing changes in actual WC pressure, estimated WC pressure, estimated differential pressure value, and command current value during ABS control.

  Hereinafter, an embodiment embodying the present invention will be described with reference to FIGS. In the following description of the present specification, the traveling direction (forward direction) of the vehicle is assumed to be the front (front of the vehicle).

  As shown in FIG. 1, the motorcycle according to the present embodiment has a driving device (not shown) for applying a driving force to the rear wheel RW, which is a driving wheel, and a braking force for the front wheel FW and the rear wheel RW. The braking device 11 is provided. The driving device includes a driving source (such as an engine or a motor) (not shown) that drives to generate a driving force corresponding to the amount of operation of the accelerator 12 by the driver, and the driving force generated by the driving source is the rear wheel RW. As a result, the vehicle travels in the traveling direction.

  The braking device 11 includes a front-wheel hydraulic pressure generating device 13f for applying a braking force to the front wheel FW, which is a driven wheel and a steering wheel, and a rear-wheel hydraulic pressure for applying a braking force to the rear wheel RW. And a generator 13r. The braking device 11 includes a brake actuator 15 having two hydraulic circuits 14f and 14r (a portion surrounded by a two-dot chain line in FIG. 1), and an electronic device as a braking control device for controlling the brake actuator 15. And a control device (hereinafter referred to as “ECU”) 16. The front wheel hydraulic circuit 14f is connected to the front wheel hydraulic pressure generator 13f and to the front wheel wheel cylinder 17f. The rear wheel hydraulic circuit 14r is connected to the rear wheel hydraulic pressure generator 13r and to the rear wheel wheel cylinder 17r.

  Note that the vehicle of the present embodiment is provided with pressure sensors SE4 and SE5 as pressure detection means for detecting wheel cylinder pressure (also referred to as “WC pressure”) in each of the wheel cylinders 17f and 17r. . From these pressure sensors SE4 and SE5, a detection signal corresponding to the actual WC pressure (also referred to as “actual WC pressure”) in the wheel cylinders 17f and 17r is output to the ECU 16.

  The front wheel hydraulic pressure generator 13f is also referred to as a master cylinder pressure (also referred to as “MC pressure”) in response to an operation of the brake lever 18 by the driver, that is, an operation to bring the brake lever 18 closer to the right handle 19 of the motorcycle. ) Is generated inside the front wheel master cylinder 20f. The rear wheel hydraulic pressure generator 13r is configured to generate MC pressure in response to the operation of the brake pedal 21 by the driver, that is, the depression of the brake pedal 21 disposed in front of the right footrest of the motorcycle. A wheel master cylinder 20r is provided. When the brake lever 18 and the brake pedal 21 are operated by the driver, the brake fluid is supplied from the master cylinders 20f and 20r into the wheel cylinders 17f and 17r via the hydraulic circuits 14f and 14r. As a result, a braking force corresponding to the WC pressure in the wheel cylinders 17f and 17r is applied to the wheels FW and RW.

  In the brake actuator 15, each of the hydraulic circuits 14f and 14r includes a pressure increasing valve (first electromagnetic valve) 24f that is a normally open electromagnetic valve disposed between the master cylinders 20f and 20r and the wheel cylinders 17f and 17r. , 24r, and pressure reducing valves (second electromagnetic valves) 25f, 25r, which are normally closed solenoid valves, are provided. Each pressure increasing valve 24f, 24r is operated so as to be in an open state when the WC pressure in each wheel cylinder 17f, 17r is increased, that is, when the WC pressure is maintained and reduced. Are operated so as to be in a closed state, that is, are closed. The pressure reducing valves 25f and 25r are closed when the WC pressure in the wheel cylinders 17f and 17r is increased and held, respectively, and are opened when the WC pressure is reduced.

  The pressure increasing valves 24f and 24r and the pressure reducing valves 25f and 25r are two-position electromagnetic valves. However, in this embodiment, when the WC pressure of the wheel cylinders 17f and 17r is increased in the ABS control described later, the pressure increasing valves 24f and 24r are opened so as to gradually increase the WC pressure. That is, the command current value Id (see FIG. 2) supplied to the electromagnetic coils (not shown) of the pressure increasing valves 24f and 24r is adjusted so as to gradually decrease.

  The hydraulic circuits 14f and 14r include reservoirs 26f and 26r for temporarily storing brake fluid flowing out from the wheel cylinders 17f and 17r via the pressure reducing valves 25f and 25r, and a drive motor 27 (for example, brushless). Pumps 28f and 28r (such as a piston pump and a gear pump) that are operated by rotation of a motor are provided. Each of these pumps 28f and 28r sucks the brake fluid in the reservoirs 26f and 26r, respectively, and directs them to connection portions 31f and 31r between the master cylinders 20f and 20r and the pressure increasing valves 24f and 24r in the hydraulic circuits 14f and 14r. Each.

Next, the ECU 16 of this embodiment will be described.
Wheel speed sensors SE1 and SE2 and pressure sensors SE4 and SE5 for detecting the wheel speeds of the wheels FW and RW are electrically connected to the input side interface of the ECU 16. Further, the valves 24f, 24r, 25f, 25r, the drive motor 27, and the like are electrically connected to the output side interface of the ECU 16. The ECU 16 individually controls the operations of the valves 24f, 24r, 25f, 25r and the drive motor 27 (that is, the pumps 28f, 28r) based on various detection signals from the various sensors SE1, SE2, SE4, SE5. . The ECU 16 estimates and calculates the vehicle body deceleration in the front-rear direction of the vehicle necessary for various braking controls based on detection signals from the wheel speed sensors SE1 and SE2.

  The ECU 16 includes a digital computer including a CPU 32, a ROM 33 and a RAM 34, a valve driver circuit (not shown) for operating the valves 24f, 24r, 25f, and 25r, and a motor (not shown) for operating the drive motor 27. Driver circuit. In the ROM 33 of the digital computer, various control processes (brake control process, etc., which will be described later), various maps (map, etc., shown in FIG. 2), various threshold values (vehicle speed threshold, pressure difference threshold, counter threshold, etc., which will be described later) Is stored in advance. The RAM 34 stores various information (wheel speed, vehicle speed, vehicle deceleration, actual WC pressure, estimated WC pressure, pressure difference, which will be described later) while the ignition switch (not shown) of the vehicle is “ON”. Each counter, each flag, etc.) are stored.

Next, various maps stored in advance in the ROM 33 will be described with reference to FIG.
The characteristic map shown in FIG. 2 shows a command current value Id supplied to an electromagnetic coil (not shown) of the pressure increasing valves 24f and 24r when an antilock brake control (also referred to as “ABS control”) described later is executed. It is a map for setting based on. As shown in FIG. 2, the command current value Id is set to a current value between “0 (zero)” and the initial current value I0 when the estimated differential pressure value ΔPd is “0 (zero)”. The The initial current value I0 is a magnitude necessary for generating an electromagnetic force having a magnitude substantially equal to a biasing force applied to a valve body (not shown) from a coil spring (not shown) of the pressure increasing valves 24f, 24r. Therefore, when the command current value Id is equal to or less than the initial current value I0, the pressure increasing valves 24f and 24r are opened. The command current value Id is set to a larger value as the estimated differential pressure value ΔPd increases when the estimated differential pressure value ΔPd is greater than “0 (zero)”. The command current value Id is set to the holding current value Ihold when the differential pressure estimated value ΔPd is the maximum differential pressure ΔPhold.

  Here, the differential pressure is a differential pressure between the MC pressure in the master cylinders 20f and 20r and the WC pressure in the wheel cylinders 17f and 17r. The estimated differential pressure value ΔPd is an estimate of the differential pressure. Value. When the command current value Id is equal to or greater than the holding current value Ihold, the pressure increase valves 24f and 24r are closed, and the increase in the WC pressure of the wheel cylinders 17f and 17r is restricted.

  Next, a braking control processing routine executed by the ECU 16 of the present embodiment will be described based on the flowchart shown in FIG. 3 and the timing chart shown in FIG. 6 shows the vehicle body speed VS and wheel speeds VWF and VWR, the estimated MC pressure Pmc of the master cylinders 20f and 20r, the estimated WC pressure Pwc_e and the actual WC pressure Pwc_r of the wheel cylinders 17f and 17r. It is a timing chart which shows an example of change of command current value Id to pressure estimate value deltaPd and pressure increase valves 24f and 24r.

  The ECU 16 executes a braking control processing routine at predetermined intervals (for example, “6 msec.”) Set in advance. In this braking control processing routine, the ECU 16 calculates the wheel speeds VWF and VWR of the wheels FW and RW based on the detection signals from the wheel speed sensors SE1 and SE2 (step S10). Subsequently, the ECU 16 calculates the vehicle body speed (also referred to as “estimated vehicle speed”) VS of at least one of the wheel speeds VWF and VWR calculated in step S10 (for example, the wheel speed VWF of the front wheel FW). (Step S11).

  Then, the ECU 16 performs an ABS control start determination process for determining whether or not an ABS control start condition for suppressing the lock of the wheels FW and RW and ensuring the steering performance of the vehicle during a brake operation by the driver is satisfied. Execute (Step S12). Specifically, the ECU 16 subtracts the wheel speeds VWF and VWR of the wheels FW and RW from the vehicle body speed VS of the vehicle, and sets the subtraction result as the slip amount of the wheels FW and RW. Further, the ECU 16 differentiates each wheel speed VWF, VWR calculated in step S10 to obtain wheel acceleration of each wheel FW, RW, and multiplies the wheel acceleration by “−1” to each wheel FW, Acquire wheel deceleration of RW. When the wheel deceleration of the wheels FW and RW is greater than or equal to a preset deceleration threshold for start determination and the slip amount of the wheels FW and RW is greater than or equal to a preset slip threshold, the ECU 16 It is determined that the control start condition is satisfied, and an ABS flag FLG1 (see FIG. 4) described later is set to “ON”. However, when the ECU 16 determines that the ABS control start condition is not satisfied, the ECU 16 sets the ABS flag FLG1 to “OFF”.

  Subsequently, the ECU 16 executes the ABS control process described in detail with reference to FIGS. 4 and 5 on the target wheel (step S13), and once ends the braking control process routine. The “target wheel” refers to a wheel that is locked or about to be locked because both the wheel deceleration and the slip amount are equal to or greater than the threshold value due to the brake operation by the driver. For example, when the brake lever 18 is operated, the front wheel FW is the target wheel, and when the brake pedal 21 is operated, the rear wheel RW is the target wheel.

  Here, the ABS control for the front wheel FW will be described. That is, as shown in the timing chart of FIG. 6, when the driver performs a brake operation, the wheel speed VWF of the front wheel FW is decelerated, and the vehicle body speed VS of the vehicle is also gradually decelerated. Then, when the first timing t11 elapses, the ABS control start condition is satisfied. Then, the pumps 28f and 28r are operated based on the rotation of the drive motor 27, the pressure increasing valve 24f provided in the front wheel hydraulic pressure circuit 14f is closed, and the pressure reducing valve 25f is opened. As a result, the WC pressure in the front wheel wheel cylinder 17f of the front wheel FW is reduced, that is, the pressure reduction control is executed. At this time, the pressure increasing valve 24r provided in the rear wheel hydraulic circuit 14r is closed so that the WC pressure in the rear wheel wheel cylinder 17r does not change.

  When the second timing t12 elapses, the slip amount of the front wheel FW (= the vehicle speed VW−the wheel speed VWF of the front wheel FW) decreases, and the pressure increase that gradually increases the WC pressure in the front wheel wheel cylinder 17f. Control (also referred to as “linear pressure increase control”) is started. That is, the open pressure reducing valve 25f is closed, and the pressure increasing valve 24f opens so that the WC pressure in the front wheel cylinder 17f is gradually increased. As described above, during the ABS control, the pressure reduction control and the pressure increase control for the WC pressure in the front wheel wheel cylinder 17f are repeatedly executed as the slip amount of the front wheel FW changes. Note that pressure holding control for holding the WC pressure in the front wheel wheel cylinder 17f may be executed between the pressure reduction control and the pressure increase control.

  Next, the ABS control processing routine (ABS control processing) in step S13 will be described based on the flowcharts shown in FIGS. 4 and 5 and the timing charts shown in FIGS. 4 and 5 are flowcharts showing an ABS control processing routine for the front wheel FW. FIG. 7 is a timing chart showing an example of changes in the estimated WC pressure Pwc_e, the actual WC pressure Pwc_r, the estimated differential pressure ΔPd of the wheel cylinders 17f and 17r and the command current value Id with respect to the pressure increasing valves 24f and 24r during the ABS control. It is.

  In the ABS control processing routine, the ECU 16 determines whether or not the ABS flag FLG1 is “ON” (step S20). However, this is limited to the case where the ABS flag FLG1 is turned “ON” when both the slip amount of the front wheel FW and the wheel deceleration are both equal to or greater than the threshold value. If the determination result in step S20 is negative (FLG1 = OFF), the ECU 16 proceeds to step S25, which will be described later, because the ABS control is not executed for the front wheel FW. Note that the ECU 16 does not execute the ABS control for the front wheel FW when the ABS flag FLG1 is “ON” when both the slip amount of the rear wheel RW and the wheel deceleration are equal to or greater than the threshold value. To step S25.

  On the other hand, if the determination result in step S20 is affirmative (FLG1 = ON), the ECU 16 determines that the ABS control for the front wheel FW is being executed, and the vehicle body speed VS calculated in step S11 is set in advance. It is determined whether or not the speed threshold value is KVS or more (step S21). The vehicle body speed threshold value KVS is a reference value for determining whether or not to terminate the ABS control for the front wheels FW, and is set in advance by experiments or simulations. If the determination result of step S21 is negative (VS <KVS), the ECU 16 proceeds to the next step S24.

  In step S24, the ECU 16 sets the ABS flag FLG1 to “OFF”. That is, the ECU 16 operates the pumps 28f and 28r for a predetermined time set in advance, and then stops the pumps 28f and 28r, that is, the drive motor 27. Then, the ECU 16 ends the ABS control for the front wheel FW. At this time, when the ABS control for the rear wheel RW is being executed, the ECU 16 continues the operation of the pumps 28f and 28r. Thereafter, the ECU 16 proceeds to the next step S25.

  In step S25, the ECU 16 resets a first counter C1 and a second counter C2, which will be described later, to “0 (zero)”. Thereafter, the ECU 16 ends the ABS control processing routine.

  On the other hand, if the determination result in step S21 is affirmative (VS ≧ KVS), the ECU 16 acquires the actual WC pressure Pwc_r in the front wheel wheel cylinder 17f based on the detection signal from the front wheel pressure sensor SE4 ( Step S26). Therefore, in this embodiment, ECU16 functions also as a wheel cylinder pressure acquisition means. Subsequently, the ECU 16 acquires a wheel cylinder pressure estimated value (also referred to as “estimated WC pressure”) Pwc_e in the front wheel wheel cylinder 17f based on the operation modes of the pressure increasing valve 24f and the pressure reducing valve 25f (step S27). Therefore, in this embodiment, ECU16 functions also as a wheel cylinder pressure estimation means.

  Here, as shown in the timing chart of FIG. 7, before the ABS control is started, the pressure increasing valve 24f is open and the pressure reducing valve 25f is closed, so that the WC pressure in the front wheel wheel cylinder 17f is closed. Is substantially equal to the MC pressure in the front wheel master cylinder 20f. That is, until the first timing t11 elapses from the 0th timing t10 when the brake operation is started, the MC pressure in the front wheel master cylinder 20f is estimated, that is, by obtaining the estimated MC pressure Pmc, The estimated WC pressure Pwc_e in the wheel cylinder 17f is acquired.

  Therefore, in the present embodiment, the ECU 16 multiplies the vehicle body deceleration of the vehicle estimated and calculated based on the detection signals from the wheel speed sensors SE1, SE2 by a predetermined first gain, and uses the multiplication result as the front wheel master cylinder 20f. Of the estimated MC pressure Pmc. Then, the ECU 16 sets the acquired estimated MC pressure Pmc as the estimated WC pressure Pwc_e in the front wheel wheel cylinder 17f. However, the estimated MC pressure Pmc obtained by the above calculation depends on the length of time (also referred to as “ABS preparation time”) from when the brake operation is started to when ABS control is started. May be different. Therefore, the estimated MC pressure Pmc obtained by the above calculation, that is, the estimated WC pressure Pwc_e, may be corrected by the ABS preparation time.

  Further, as shown in FIG. 7A, the amount of change per unit time of the actual WC pressure during the decompression control in the ABS control, that is, the decompression amount is substantially proportional to the elapsed time after the decompression control is started. It becomes a relationship. On the other hand, the amount of change per unit time of the actual WC pressure during the pressure increase control in the ABS control, that is, the pressure increase amount decreases as the valve body (not shown) approaches the valve seat (not shown) of the pressure increase valves 24f and 24r. That is, the relationship is almost inversely proportional to the magnitude of the command current value Id for the pressure increasing valves 24f and 24r (see FIGS. 7A and 7C). Therefore, in the present embodiment, during the pressure increase control, the ECU 16 controls the command current value Id, the pressure increase control time, the flow rate of the brake fluid according to the command current value Id preset for each of the pressure increase valves 24f and 24r, and Based on the estimated increased pressure in the wheel cylinders 17f and 17r corresponding to the flow rate, the estimated WC pressure Pwc_e in the front wheel wheel cylinder 17f is acquired. As an example, the ECU 16 estimates the amount of increase in the WC pressure per time (hereinafter referred to as “unit time”) corresponding to the predetermined period based on the flow rate of the brake fluid according to the command current value Id. Then, the ECU 16 integrates the acquired amount of increase in WC pressure per unit time with the previously calculated estimated WC pressure Pwc_e, and sets the accumulated result as the current estimated WC pressure Pwc_e. Further, the ECU 16 multiplies a time corresponding to the predetermined period by a predetermined second gain during the pressure reduction control. Then, the ECU 16 subtracts the multiplication result (= time corresponding to a predetermined period × second gain) from the previously calculated estimated WC pressure Pwc_e, and sets the subtraction result as the current estimated WC pressure Pwc_e.

  Returning to the flowcharts of FIG. 4 and FIG. 5, when the estimated WC pressure Pwc_e is acquired, the ECU 16 executes a control switching determination process for determining whether it is a timing to switch from the pressure increase control to the pressure decrease control. (Step S28). That is, no current is supplied to the pressure reducing valve 25f during pressure increase control. Further, during the pressure reduction control, a current is supplied to the pressure reducing valve 25f. Therefore, the ECU 16 is not supplied with current to the pressure reducing valve 25f at the time when the previous ABS control process is performed on the front wheel FW, and is supplied with current at the time when the current ABS control process is executed. In this case, it is determined that it is time to switch from the pressure increase control to the pressure decrease control, and the switching flag FLG2 is set to “ON”. On the other hand, when the current is supplied to the pressure reducing valve 25f when the previous ABS control process is executed, and when the current is not supplied to the pressure reducing valve 25f when the current ABS control process is executed, Sets the switching flag FLG2 to “OFF”.

  Then, the ECU 16 determines whether or not the switching flag FLG2 is “ON” (step S29). If this determination result is a negative determination (FLG2 = OFF), the ECU 16 proceeds to step S34 to be described later. On the other hand, if the determination result in step S29 is affirmative (FLG2 = ON), the ECU 16 determines that the front wheel wheel cylinder 17f acquired in step S27 from the actual WC pressure Pwc_r in the front wheel cylinder 17f acquired in step S26. The estimated WC pressure Pwc_e is subtracted to obtain a pressure difference Pwc_sub (step S30). That is, in step S30, a deviation amount (pressure difference Pwc_sub) of the estimated value (estimated WC pressure Pwc_e) with respect to the actually measured value (actual WC pressure Pwc_r) at the time of switching from the pressure increase control to the pressure reduction control is detected.

  Subsequently, the ECU 16 determines whether or not the pressure difference Pwc_sub acquired in step S30 is equal to or greater than a first pressure difference threshold value KPwc1 (for example, 2 MPa) set to a positive value in advance (step S31). If this determination result is affirmative (Pwc_sub ≧ KPwc1), the ECU 16 increments the first counter C1 by “1” and resets the second counter C2 to “0 (zero)” (step S32). The first counter C1 counts the number of consecutive times that step S31 is affirmative during one ABS control for the front wheel FW. Then, the ECU 16 determines whether or not the first counter C1 updated in step S32 is equal to or greater than a first counter threshold value KC1 (for example, three times) as a predetermined number of times set in advance (step S33).

  Incidentally, the detection signal from the pressure sensors SE4 and SE5 may contain a noise component. That is, the actual WC pressure Pwc_r, which is an actual measurement value of the WC pressure in the wheel cylinders 17f and 17r, may be a value that also includes a noise component included in the detection signal. In this case, even if the pressure difference Pwc_sub is calculated in step S30, the calculation result is not necessarily correct. If the actual WC pressure Pwc_r is a correct value and there is really a difference between the actual WC pressure Pwc_r and the estimated WC pressure Pwc_e, the pressure difference Pwc_sub is continuously greater than or equal to the first pressure difference threshold KPwc1. Should be. Therefore, in the present embodiment, the first counter threshold value KC1 is set in advance in order to prevent erroneous detection that the pressure difference Pwc_sub is equal to or greater than the first pressure difference threshold value KPwc1.

When the determination result in step S33 is negative (C1 <KC1), the ECU 16 proceeds to the next step S34.
In step S34, the ECU 16 sets the command current value Id supplied to the pressure increasing valve 24f during the pressure reduction control to the holding current value Ihold, and sets the command current value Id based on the characteristic map shown in FIG. 2 during the pressure increase control. . Thereafter, the ECU 16 proceeds to step S36, which will be described later.

  On the other hand, if the determination result in step S33 is affirmative (C1 ≧ KC1), the ECU 16 has a WC pressure in the front wheel cylinder 17f that is too high than planned, that is, the braking force for the front wheel FW that is the target wheel is large. Judge that it is too much. Then, the ECU 16 sets the actual pressure increase rate of the actual WC pressure Pwc_r in the front wheel cylinder 17f at the time of the next pressure increase control to be slower than the pressure increase rate of the actual WC pressure Pwc_r at the previous pressure increase control. One correction process is performed (step S35). Specifically, the ECU 16 sets the command current value Id to be supplied to the pressure increasing valve 24f so that the pressure increasing speed of the actual WC pressure Pwc_r at the next pressure increasing control becomes slower as the latest pressure difference Pwc_sub is larger. . That is, in the first correction process, the command current value Id is adjusted so that the pressure increase rate of the actual WC pressure Pwc_r is slower than when the pressure increase control is executed using the characteristic map shown in FIG. Thereafter, the ECU 16 proceeds to the next step S36.

  In step S36, the ECU 16 performs an output process for operating the pressure increasing valve 24f and the pressure reducing valve 25f. That is, the ECU 16 sets the duty ratio of the voltage applied to the pressure increasing valve 24f so that the command current value Id set in step S34, step S35 and step S40 described later is supplied to the pressure increasing valve 24f. The ECU 16 closes the pressure reducing valve 25f without supplying current to the pressure reducing valve 25f during pressure increase control. On the other hand, the ECU 16 supplies current to the pressure reducing valve 25f during pressure reduction control, and opens the pressure reducing valve 25f. That is, the ECU 16 performs current ON / OFF control on the pressure reducing valve 25f (and the pressure reducing valve 25r). Therefore, in this embodiment, ECU16 functions also as a solenoid valve control means. Thereafter, the ECU 16 ends the ABS control processing routine.

  In this embodiment, the pressure increasing valves 24f and 24r are controlled by PWM (Pulse Width Modulation). Therefore, a period in which the signal level is “Hi” and a period in which the signal level is “Low” are repeated in the drive signals output to the pressure increasing valves 24f and 24r. The ratio of the period in which the signal level is “Hi” with respect to the time corresponding to one cycle of the drive signal is called “Duty ratio”. Therefore, when the duty ratio is increased, the period during which the signal level is “Hi” in one cycle is increased, and as a result, the command current value Id for the control target (for example, the pressure increasing valve 24f) is increased.

  Here, as shown in the timing chart of FIG. 6, when the actual WC pressure Pwc_r in the wheel cylinder 17f is higher than the estimated WC pressure Pwc_e, the estimated differential pressure value ΔPd is larger than the actual differential pressure. It is to become. Therefore, during the pressure increase control, the command current value Id for the pressure increase valve 24f is larger than the command current value that should be supplied to the pressure increase valve 24f. At the third timing t13 when the pressure increase control is switched to the pressure reduction control, the pressure difference Pwc_sub at that time becomes less than the first pressure difference threshold KPwc1. That is, the first counter C1 is “0 (zero)”. Therefore, in the subsequent pressure increase control started from the fourth timing t14, the command current value Id for the pressure increase valve 24f is set based on the characteristic map shown in FIG.

  However, at the fifth timing t15 when the pressure increase control is switched to the pressure decrease control, the pressure difference Pwc_sub is equal to or greater than the first pressure difference threshold KPwc1, and the first counter C1 is changed from “0 (zero)” to “1”. Incremented to. When the pressure difference Pwc_sub is less than the first pressure difference threshold value KPwc1 at the sixth timing t16 when the pressure increasing control is switched to the pressure reducing control thereafter, the first counter C1 is reset to “0 (zero)”. . On the other hand, when the pressure difference Pwc_sub at the sixth timing t16 is greater than or equal to the first pressure difference threshold value KPwc1, the first counter C1 becomes “2”. Further, when the pressure difference Pwc_sub becomes equal to or larger than the first pressure difference threshold KPwc1 at the seventh timing t17 when the pressure increase control is switched to the pressure reduction control thereafter, the first counter C1 becomes “3”.

  Then, the pressure reduction control started from the seventh timing t17 ends, and in the pressure increase control started from the eighth timing t18, the rate of decrease in the command current value Id supplied to the pressure increase valve 24f is changed. That is, in the pressure increase control up to the previous time, the command current value Id is set to a value corresponding to the estimated differential pressure value ΔPd at the time when the pressure increase control is started based on the characteristic map shown in FIG. It becomes small based on. However, in the pressure increasing control started from the eighth timing t18, the command current value Id is adjusted regardless of the characteristic map shown in FIG. Therefore, as shown in FIG. 6E, the decrease rate of the command current value Id is the decrease rate of the command current value Id during the pressure increase control up to the previous time (the decrease rate indicated by the two-dot chain line from the eighth timing t18. ) Is set later. As a result, as shown in FIG. 6C, in the pressure increasing control started from the eighth timing t18, the pressure increasing speed of the actual WC pressure Pwc_r is the pressure increasing speed (first speed) at the time of the pressure increasing control up to the previous time. 8 from a timing t18 of 8 and a pressure increase speed indicated by a two-dot chain line). However, even during such pressure increase control, the estimated differential pressure value ΔPd is estimated as if the command current value Id is set based on the characteristic map shown in FIG.

  Then, at the ninth timing t19 when the next pressure reduction control is started from the pressure increase control, the pressure difference Pwc_sub between the actual WC pressure Pwc_r and the estimated WC pressure Pwc_e approaches “0 (zero)”. Therefore, as shown in FIG. 6D, the differential pressure estimated value ΔPd approaches the actual differential pressure. Then, the first counter C1 is reset to “0 (zero)”. In the subsequent pressure increase control, the command current value Id supplied to the pressure increase valve 24f is adjusted again based on the characteristic map shown in FIG. As described above, by performing a correction process that brings the actual WC pressure Pwc_r closer to the estimated WC pressure Pwc_e, appropriate braking control is performed on the front wheels FW. Therefore, the behavior stability of the vehicle during the ABS control is further improved.

  Returning to the flowchart shown in FIG. 5, when the determination result in step S31 is negative (Pwc_sub <KPwc1), the ECU 16 sets the second pressure difference threshold value in which the pressure difference Pwc_sub calculated in step S30 is set to a negative value in advance. It is determined whether it is below KPwc2 (for example, -2 MPa) (step S37). If the determination result is negative (Pwc_sub> KPwc2), the ECU 16 resets the counters C1 and C2 to “0 (zero)” (step S38), and the process proceeds to step S34 described above. On the other hand, when the determination result of step S37 is affirmative (Pwc_sub ≦ KPwc2), the ECU 16 resets the first counter C1 to “0 (zero)” and increments the second counter C2 by “1” ( Step S39). The second counter C2 counts the number of consecutive times that step S37 is affirmative during one ABS control for the front wheel FW. Then, the ECU 16 determines whether or not the second counter C2 updated in step S39 is equal to or larger than a second counter threshold value KC2 (for example, three times) as a predetermined number of times set in advance (step S40). The reason for setting the second counter threshold value KC2 is the same as the reason for setting the first counter threshold value KC1.

  When the determination result in step S40 is negative (C2 <KC2), the ECU 16 proceeds to step S34 described above. On the other hand, when the determination result of step S40 is affirmative (C2 ≧ KC2), the ECU 16 has a WC pressure in the front wheel cylinder 17f that is too low than planned, that is, the braking force for the front wheel FW that is the target wheel is small. Judge that it is too much. Then, the ECU 16 sets the actual pressure increase speed of the actual WC pressure Pwc_r in the front wheel cylinder 17f at the time of the next pressure increase control to be higher than the pressure increase speed of the actual WC pressure Pwc_r at the previous pressure increase control. 2 correction processing is performed (step S41). Specifically, the ECU 16 increases the pressure increase speed of the actual WC pressure Pwc_r at the next pressure increase control as the latest pressure difference Pwc_sub is smaller, that is, as the absolute value of the latest pressure difference Pwc_sub is larger. A command current value Id to be supplied to the pressure increasing valve 24f is set. Subsequently, the ECU 16 executes step S36 described above for the process, and thereafter ends the ABS control process routine.

  Here, as shown in the timing chart of FIG. 7, when the actual WC pressure Pwc_r in the wheel cylinder 17f is lower than the estimated WC pressure Pwc_e, the estimated differential pressure value ΔPd is smaller than the actual differential pressure. It is to become. Therefore, during the pressure increase control, the command current value Id for the pressure increase valve 24f is smaller than the command current value that should be supplied to the pressure increase valve 24f. At the first timing t21 when the pressure increase control is switched to the pressure reduction control, the pressure difference Pwc_sub at that time is larger than the second pressure difference threshold value KPwc2. That is, the second counter C2 becomes “0 (zero)”. Therefore, in the pressure increase control started from the second timing t22 thereafter, the command current value Id for the pressure increase valve 24f is set based on the characteristic map shown in FIG.

  However, when the pressure difference Pwc_sub becomes equal to or smaller than the second pressure difference threshold value KPwc2 at the third timing t23 when the pressure increase control is switched to the pressure decrease control, the second counter C2 is changed from “0 (zero)” to “1”. Incremented to. When the pressure difference Pwc_sub is equal to or smaller than the second pressure difference threshold value KPwc2 at the fourth timing t24 when the pressure increasing control is switched to the pressure reducing control thereafter, the second counter C2 becomes “2”. Further, when the pressure difference Pwc_sub becomes equal to or smaller than the second pressure difference threshold value KPwc2 at the fifth timing t25 when the pressure increase control is switched to the pressure reduction control thereafter, the second counter C2 becomes “3”.

  Then, the pressure reduction control started from the fifth timing t25 ends, and in the pressure increase control started from the sixth timing t26, the rate of decrease in the command current value Id supplied to the pressure increase valve 24f is changed. That is, in the pressure increase control up to the previous time, the command current value Id is set to a value corresponding to the estimated differential pressure value ΔPd at the time when the pressure increase control is started based on the characteristic map shown in FIG. It becomes small based on. However, in the pressure increasing control started from the sixth timing t26, the command current value Id is adjusted regardless of the characteristic map shown in FIG. Therefore, as shown in FIG. 7C, the decrease rate of the command current value Id is the decrease rate of the command current value Id during the pressure increase control up to the previous time (the decrease rate indicated by the two-dot chain line from the sixth timing t26). ) Is set faster. As a result, as shown in FIG. 7A, in the pressure increase control started from the sixth timing t26, the pressure increase speed of the actual WC pressure Pwc_r is the pressure increase speed (first speed) at the time of the pressure increase control up to the previous time. 6 from the timing t26 of 6 and a pressure increase speed indicated by a two-dot chain line).

  Then, at the seventh timing t27 when the next pressure reduction control is started from the pressure increase control, the pressure difference Pwc_sub between the actual WC pressure Pwc_r and the estimated WC pressure Pwc_e approaches “0 (zero)”. Therefore, as shown in FIG. 7B, the estimated differential pressure value ΔPd approaches the actual differential pressure, and the second counter C2 is reset to “0 (zero)”. In the subsequent pressure increase control, the command current value Id supplied to the pressure increase valve 24f is adjusted again based on the characteristic map shown in FIG. In this way, by performing a correction process that brings the estimated WC pressure Pwc_e closer to the actual WC pressure Pwc_r, appropriate braking control is performed on the front wheels FW. Therefore, the behavior stability of the vehicle during the ABS control is further improved.

  Note that the ABS control processing routine for the rear wheel RW is substantially the same as the ABS control processing routine for the front wheel FW described above. That is, the ECU 16 sets the command current value Id to be supplied to the pressure increasing valve 24r based on the pressure difference Pwc_sub between the actual WC pressure Pwc_r and the estimated WC pressure Pwc_e in the rear wheel wheel cylinder 17r. By performing such control, it is possible to execute appropriate braking control for the rear wheel RW as in the ABS control for the front wheel FW. Incidentally, the actual WC pressure Pwc_r in the rear wheel wheel cylinder 17r is acquired based on a detection signal from the rear wheel pressure sensor SE5.

Therefore, in this embodiment, the following effects can be obtained.
(1) At the time of ABS control, the estimated WC pressure Pwc_e in the wheel cylinder (for example, the front wheel wheel cylinder 17f) of the target wheel (for example, the front wheel FW) is acquired, and the wheel cylinder is based on the detection signals from the pressure sensors SE4 and SE5. The actual WC pressure Pwc_r is detected. During the ABS control, the operation modes of the pressure increasing valves 24f and 24r are adjusted so that the actual WC pressure Pwc_r approaches the estimated WC pressure Pwc_e. Therefore, during ABS control, the braking force for the target wheel is adjusted appropriately. Therefore, by adjusting the operation mode of the pressure increasing valves 24f and 24r based on the detection signals from the pressure sensors SE4 and SE5 during the ABS control, it is possible to contribute to further stabilization of the vehicle behavior.

  (2) When the pressure difference Pwc_sub between the estimated WC pressure Pwc_e and the actual WC pressure Pwc_r is greater than or equal to the first pressure difference threshold value KPwc1 during the ABS control, the target wheel (for example, the front wheel FW) has a braking force having a predetermined magnitude. A braking force greater than (that is, a braking force having a magnitude corresponding to the estimated WC pressure Pwc_e) is applied. Therefore, a so-called hunting phenomenon that shortens the execution time of the pressure increase control during the ABS control may occur. Therefore, in the present embodiment, when the pressure difference Pwc_sub is equal to or greater than the first pressure difference threshold KPwc1, the pressure increasing valves 24f and 24r are controlled so that the pressure increasing speed of the actual WC pressure Pwc_r during the pressure increasing control is slow. Is done. Therefore, the occurrence of the hunting phenomenon can be suppressed or the hunting phenomenon can be quickly eliminated.

  (3) When the pressure difference Pwc_sub between the estimated WC pressure Pwc_e and the actual WC pressure Pwc_r is equal to or smaller than the second pressure difference threshold value KPwc2 during the ABS control, the target wheel (for example, the front wheel FW) has a predetermined size. A braking force smaller than the braking force (that is, a braking force having a magnitude corresponding to the estimated WC pressure Pwc_e) is applied. In this case, there is a possibility that the braking distance of the vehicle becomes longer than when a braking force having an appropriate magnitude is applied to the target wheel. Therefore, in the present embodiment, when the pressure difference Pwc_sub is equal to or smaller than the second pressure difference threshold value KPwc2, the pressure increasing valves 24f and 24r are controlled so that the pressure increasing speed of the actual WC pressure Pwc_r at the time of pressure increasing control is increased. Is done. Therefore, the braking distance of the vehicle can be shortened while stabilizing the behavior of the vehicle during the ABS control.

  (4) In the present embodiment, the pressure increasing valves 24f and 24r are controlled based on the pressure difference Pwc_sub between the estimated WC pressure Pwc_e and the actual WC pressure Pwc_r at the time of switching from pressure increasing control to pressure reducing control. Therefore, as compared with the case where the timing for acquiring the pressure difference Pwc_sub is different every time, the detection accuracy of the deviation of the actual WC pressure Pwc_r from the estimated WC pressure Pwc_e is improved as the acquisition timing of the pressure difference Pwc_sub is unified. Can do.

  (5) When the pressure difference Pwc_sub between the estimated WC pressure Pwc_e and the actual WC pressure Pwc_r is equal to or greater than the first pressure difference threshold KPwc1 or equal to or less than the second pressure difference threshold KPwc2, the pressure increase rate of the actual WC pressure Pwc_r is reduced. Can be set during control execution. Therefore, compared with the case where the pressure increase speed of the actual WC pressure Pwc_r is corrected based on the pressure difference Pwc_sub between the estimated WC pressure Pwc_e and the actual WC pressure Pwc_r at the time of switching from the pressure decrease control to the pressure increase control, the pressure increasing valve 24f, The time for correcting the operation mode of 24r can be obtained. Therefore, the pressure increase rate of the actual WC pressure Pwc_r can be corrected to the planned pressure increase rate.

  (6) When the pressure difference Pwc_sub between the estimated WC pressure Pwc_e and the actual WC pressure Pwc_r is not less than the first pressure difference threshold KPwc1 or not more than the second pressure difference threshold KPwc2, the command current value Id supplied to the pressure increasing valves 24f, 24r is The pressure is corrected to a value corresponding to the pressure difference Pwc_sub. Therefore, after the correction of the command current value Id, the braking control for the target wheel (for example, the front wheel FW) can be appropriately executed, which can contribute to the improvement of the stability of the behavior of the vehicle during the ABS control.

  (7) When the first counter C1 is not provided, the first correction process is performed when it is detected only once that the pressure difference Pwc_sub between the estimated WC pressure Pwc_e and the actual WC pressure Pwc_r becomes equal to or greater than the first pressure difference threshold KPwc1. Is executed. If the second counter C2 is not provided, the second correction process is executed when it is detected only once that the pressure difference Pwc_sub is equal to or less than the second pressure difference threshold value KPwc2. In such a case, there is a risk of erroneous determination due to noise components included in the detection signals from the pressure sensors SE4 and SE5. In this regard, in the present embodiment, the first correction control is not executed when the first counter C1 is less than the first counter threshold KC1. Further, when the second counter C2 is less than the second counter threshold value KC2, the second correction control is not executed. Therefore, it is possible to suppress the occurrence of a braking control error for the target wheel due to the erroneous determination.

The embodiment may be changed to another embodiment as described below.
In the embodiment, the counter threshold values KC1 and KC2 may be changed to any number other than three times. However, when setting each of the counter threshold values KC1 and KC2 to a value larger than 3 times (for example, 5 times), the first pressure difference threshold value KPwc1 is set to a value smaller than “2 MPa” (for example, 1 MPa) and the second pressure It is desirable to set the difference threshold value KPwc2 to a value (for example, -1 MPa) larger than "-2 MPa". Further, when each of the counter threshold values KC1 and KC2 is set to a value smaller than 3 times (for example, 2 times), the first pressure difference threshold value KPwc1 is set to a value larger than “2 MPa” (for example, 4 MPa) and the second pressure It is desirable to set the difference threshold value KPwc2 to a value smaller than “−2 MPa” (for example, −4 MPa).

In the embodiment, the pressure difference Pwc_sub may be acquired based on the estimated WC pressure Pwc_e and the actual WC pressure Pwc_r at the time of switching from the pressure reduction control to the pressure increase control.
In the embodiment, in each correction process, the pressure increase speed of the actual WC pressure Pwc_r is set to a speed corresponding to an average value of three consecutive pressure differences Pwc_sub, not a speed corresponding to the latest pressure difference Pwc_sub. May be. For example, in the first correction process, as shown in FIG. 6, the average value of the pressure difference Pwc_sub at the fifth timing t15, the sixth timing t16, and the seventh timing t17 is calculated to increase the actual WC pressure Pwc_r. The pressure speed may be set to a speed according to the average value.

  In the embodiment, in the first correction process and the second correction process, the pressure increase rate of the actual WC pressure Pwc_r in the wheel cylinders 17f and 17r is adjusted according to the pressure difference Pwc_sub. However, in the first correction process, if the pressure increase speed of the actual WC pressure Pwc_r is slower than the pressure increase speed of the actual WC pressure Pwc_r during the previous pressure increase control, the degree of correction of the pressure increase speed is the pressure difference. It may be constant regardless of Pwc_sub. Similarly, in the second correction process, if the pressure increase speed of the actual WC pressure Pwc_r is faster than the pressure increase speed of the actual WC pressure Pwc_r in the previous pressure increase control, the degree of correction of the pressure increase speed is the pressure It may be constant regardless of the difference Pwc_sub.

  In the embodiment, the pressure difference threshold values KPwc1 and KPwc2 need not be set. In this case, when executing the pressure increase control, it is desirable to adjust the command current value Id supplied to the pressure increase valves 24f and 24r so that the pressure difference Pwc_sub at the end of the previous pressure increase control becomes small.

  In the embodiment, when the pressure increase control of the pressure increase valves 24f and 24r is performed, the duty ratio of the voltage applied to the pressure increase valves 24f and 24r is gradually changed. However, when the first correction process is executed, control may be performed so that the voltage applied to the pressure increasing valves 24f and 24r is gradually increased. In this case, the speed of increasing the actual WC pressure Pwc_r in the wheel cylinders 17f and 17r can be made slower than when the first correction process is not executed.

In the embodiment, an acceleration sensor (also referred to as “G sensor”) for detecting vehicle body acceleration in the front-rear direction of the vehicle may be provided in the vehicle.
In the embodiment, the vehicle may be embodied as an automatic three-wheeled vehicle in which one front wheel is disposed on the front side in the traveling direction and two rear wheels are disposed on the rear side in the traveling direction. The vehicle may be embodied as an automatic three-wheeled vehicle in which two front wheels are disposed on the front side in the traveling direction and one rear wheel is disposed on the rear side in the traveling direction.

Next, the technical idea that can be grasped from the above embodiment and another embodiment will be added below.
(A) Depressurization control for reducing the wheel cylinder pressure (Pwc_r) in the wheel cylinders (17f, 17r) for applying braking force to the wheels (FW, RW) when the anti-lock brake control start condition is satisfied. In order to repeat the pressure increase control for gradually increasing the wheel cylinder pressure (Pwc_r), the master cylinder (20f, 20r) that generates the master cylinder pressure (Pmc) corresponding to the brake operation and the wheel cylinder (17f, 17r), and the first solenoid valve (24f, 24r) opened during the pressure increase control and the second solenoid valve (25f, 25r) opened during the pressure reduction control are operated. In the vehicle braking control method for the vehicle, the vehicle has a wheel cylinder pressure (Pwc_) in the wheel cylinder (17f, 17r). ) Is detected, and a wheel cylinder pressure estimating step (S27) for obtaining a wheel cylinder pressure estimated value (Pwc_e) in the wheel cylinder (17f, 17r) is provided. A wheel cylinder pressure acquisition step (S26) for acquiring a wheel cylinder pressure (Pwc_r) in the wheel cylinders (17f, 17r) based on a detection signal from the pressure detection means (SE4, SE5), and the wheel cylinder pressure The first solenoid valves (24f, 24r) so that the wheel cylinder pressure (Pwc_r) acquired in the acquisition step (S26) approaches the wheel cylinder pressure estimated value (Pwc_e) acquired in the wheel cylinder pressure estimation step (S27). ) Actuating solenoid valve control step (S34, S3) , S36, S41) and the braking control method for a vehicle characterized in that it comprises a.

  16 ... Wheel cylinder pressure estimation means, wheel cylinder pressure acquisition means, ECU as electromagnetic valve control means, 17f, 17r ... wheel cylinder, 20f, 20r ... master cylinder, 24f, 24r ... pressure increase valve as first electromagnetic valve, 25f, 25r ... pressure reducing valve as second solenoid valve, FW, RW ... wheel, Id ... command current value, KC1, KC2 ... counter threshold value as a predetermined number of times, KPwc1 ... first pressure difference threshold value, KPwc2 ... second pressure Difference threshold, Pmc: estimated MC pressure, Pwc_e: estimated WC pressure, Pwc_sub: pressure difference, Pwc_r: actual WC pressure, SE4, SE5: pressure sensor as pressure detecting means.

Claims (5)

Pressure reduction control and wheel cylinder for reducing the wheel cylinder pressure (Pwc_r) in the wheel cylinder (17f, 17r) for applying a braking force to the wheel (FW, RW) when the anti-lock brake control start condition is satisfied A master cylinder (20f, 20r) that generates a master cylinder pressure (Pmc) corresponding to a brake operation and the wheel cylinders (17f, 17r) so that the pressure increase control for gradually increasing the pressure (Pwc_r) is repeated. Between the first solenoid valve (24f, 24r) disposed between the first solenoid valve (24f, 24r) and opened during the pressure increase control, and the second solenoid valve (25f, 25r) opened during the pressure reduction control. In the control device,
The vehicle is provided with pressure detection means (SE4, SE5) for detecting the wheel cylinder pressure (Pwc_r) in the wheel cylinder (17f, 17r),
Wheel cylinder pressure estimating means (16, S27) for obtaining a wheel cylinder pressure estimated value (Pwc_e) in the wheel cylinder (17f, 17r);
Wheel cylinder pressure acquisition means (16, S26) for acquiring a wheel cylinder pressure (Pwc_r) in the wheel cylinder (17f, 17r) based on a detection signal from the pressure detection means (SE4, SE5);
The wheel cylinder pressure (Pwc_r) acquired by the wheel cylinder pressure acquisition unit (16, S26) approaches the wheel cylinder pressure estimation value (Pwc_e) acquired by the wheel cylinder pressure estimation unit (16, S27). A vehicle braking control device comprising: electromagnetic valve control means (16, S34, S35, S36, S41) for adjusting an opening operation of the first electromagnetic valve (24f, 24r). The electromagnetic valve control means (16, S34, S35, S36, S41) includes a wheel cylinder pressure estimated value (Pwc_e) acquired by the wheel cylinder pressure estimating means (16, S27) and a wheel cylinder pressure acquiring means (16 , S26) when the absolute value of the pressure difference (Pwc_sub) with respect to the wheel cylinder pressure (Pwc_r) obtained is greater than or equal to the preset absolute value of the pressure difference threshold (KPwc1, KPwc2), the wheel cylinder pressure ( 2. The vehicle braking control device according to claim 1, wherein an opening operation of the first electromagnetic valve is adjusted so that Pwc_r) approaches the estimated wheel cylinder pressure value (Pwc_e). 3. The electromagnetic valve control means (16, S34, S35, S36, S41) includes a wheel cylinder pressure estimated value (Pwc_e) acquired by the wheel cylinder pressure estimating means (16, S27) and a wheel cylinder pressure acquiring means (16 , S26), when the absolute value of the pressure difference (Pwc_sub) with respect to the wheel cylinder pressure (Pwc_r) is equal to or larger than the absolute value of a preset pressure difference threshold (KPwc1, KPwc2), the pressure difference (Pwc_sub) The vehicle braking control device according to claim 2, wherein a command current value (Id) to be supplied to the first electromagnetic valve (24f, 24r) is adjusted in accordance with (1). The wheel cylinder pressure estimation means (16, S27) and the wheel cylinder pressure acquisition means (16, S26) are the time point when the pressure increase control is switched to the pressure reduction control or the pressure reduction control during the antilock brake control. 4. The wheel cylinder pressure estimated value (Pwc_e) and the wheel cylinder pressure (Pwc_r) at the time of switching to the pressure increase control can be respectively acquired. 5. Vehicle braking control device. The wheel cylinder pressure estimation means (16, S27) and the wheel cylinder pressure acquisition means (16, S26) are the time point when the pressure increase control is switched to the pressure reduction control or the pressure reduction control during the antilock brake control. A wheel cylinder pressure estimated value (Pwc_e) and a wheel cylinder pressure (Pwc_r) at the time of switching to the pressure increase control can be respectively acquired.
The electromagnetic valve control means (16, S34, S35, S36, S41) includes a wheel cylinder pressure estimated value (Pwc_e) acquired by the wheel cylinder pressure estimating means (16, S27) and a wheel cylinder pressure acquiring means (16 , When the absolute value of the pressure difference (Pwc_sub) with respect to the wheel cylinder pressure (Pwc_r) acquired by S26) is equal to or greater than the pressure difference threshold (KPwc1, KPwc2) for a predetermined number of times (KC1, KC2), The opening operation of the first electromagnetic valve (24f, 24r) is adjusted so that the wheel cylinder pressure (Pwc_r) approaches the estimated wheel cylinder pressure value (Pwc_e). A braking control device for a vehicle according to claim 1.

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