JP2008044416A - Braking control device of vehicle and braking control method of vehicle - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a braking control device of a vehicle, and a braking control method of the vehicle, capable of restraining unnecessary execution of turning time braking control. <P>SOLUTION: This vehicle is mounted with an ECU, and the ECU constitutes the braking control device. This ECU detects a steering angle A of a steering wheel based on an input signal from a steering angle sensor by an arithmetic operation, and detects steering torque T applied to the steering wheel based on an input signal from a steering torque sensor by an arithmetic operation. The ECU executes the turning time braking control so as to increase brake liquid pressure BP in a wheel cylinder of a rear wheel on the inside in the turning direction of the vehicle, when an absolute value of the steering angle A is a steering angle threshold value KA or more and the steering torque T is a torque threshold value KT or more. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a vehicle braking control device that controls a braking force applied to each wheel of a vehicle, and a vehicle braking control method.

  2. Description of the Related Art Conventionally, as a vehicle braking control device that executes braking control for reducing a turning radius when a vehicle turns, for example, a vehicle braking control device described in Patent Document 1 (hereinafter referred to as a “conventional braking control device”). Proposed. This conventional brake control device detects the steering angle of the steering wheel, and determines that the steering wheel has been steered to the maximum when the detected steering angle is equal to or greater than a preset steering angle threshold. In this conventional braking control device, when it is determined that the steering wheel has been steered to the maximum, a braking force is applied to the rear wheel on the inner side in the turning direction of the vehicle (or the right rear wheel when turning in the right direction). The braking control during turning is executed. “Maximum steering” refers to a state in which the steering wheel is steered to the maximum in a certain direction (right or left in the rotational direction).

Thus, in a vehicle that turns in a state in which the braking control during turning is executed, the turning radius is smaller than in a vehicle that does not execute the braking control during turning, so that a small turn is effective. Therefore, when this conventional braking control device is mounted on a general passenger car (hereinafter referred to as “vehicle”), when a driver who finds an obstacle in the traveling direction of the vehicle performs maximum steering on the steering wheel, the turning radius is set. Since the braking control during turning to be reduced is executed, it has been possible to satisfactorily avoid obstacles that have appeared in the traveling direction of the vehicle.
JP-A-8-207823 (Claim 1)

  By the way, when it is determined that the steering wheel has been steered to the maximum, the conventional braking control device uniformly performs the braking control during turning. However, the vehicle driver may steer the steering wheel to the maximum even when the vehicle is parked at a predetermined position in the parking lot, for example. In such a case, even when the steering wheel is steered to the maximum, the braking control during turning that makes the turning radius small is unnecessary. Therefore, in the conventional braking control device, the braking control at the time of turning is executed unnecessarily, so that the actuator that is driven when the braking force is applied to the rear wheel inside the turning direction of the vehicle, and the rear side inside the turning direction of the vehicle. There has been a problem that the load on the wheel (tire) becomes very large.

  The present invention has been made in view of such circumstances, and an object thereof is to provide a vehicle braking control device and a vehicle braking control method capable of suppressing unnecessary execution of braking control during turning. is there.

  In order to achieve the above object, the invention according to claim 1 relating to a vehicle braking control device is a vehicle in which wheels (FR, FL, RR, RL) are arranged on both left and right sides with respect to the traveling direction of the vehicle (C). In the braking control device (11) of the vehicle (C) that is mounted on (C) and controls the braking force (BP) applied to each wheel (FR, FL, RR, RL), the steering of the vehicle (C) Steering angle calculating means (S13) for calculating the steering angle (A) of (24), steering torque calculating means (S15) for calculating the steering torque (T) applied to the steering (24), and the steering angle calculating means The absolute value of the steering angle (A) calculated in (S13) is equal to or greater than a preset steering angle threshold (KA), and the steering torque (T) calculated in the steering torque calculation means (S15). Is preset Control means (S19) for executing braking control during turning in which braking force (BP) is applied to the wheel (RR) on the inner side in the turning direction of the vehicle (C) when the torque threshold value (KT) is not less than The summary is provided.

  In the above configuration, even if the absolute value of the steering angle of the steering wheel becomes equal to or greater than the steering angle threshold value, the driver is steered by the steering wheel with the intention of causing the vehicle to execute the braking control during turning. Unless the steering torque is applied to the steering, the braking control during turning is not executed. Therefore, unnecessary execution of the braking control during turning can be suppressed.

  According to a second aspect of the present invention, in the vehicle braking control apparatus according to the first aspect of the present invention, the vehicle further includes a vehicle body speed calculating means (S11) for calculating a vehicle body speed (VS) of the vehicle (C). S19) is to execute the braking control during turning when the vehicle body speed (VS) calculated by the vehicle body speed calculating means (S11) is equal to or less than a preset vehicle body speed threshold (KVS). And

  In general, when turning the vehicle when the vehicle body speed value is larger than the vehicle body speed threshold value, it is possible to reduce the turning radius by applying substantially the same braking force to each wheel. There is no need for the vehicle to perform control. In this regard, in the present invention, when the vehicle body speed is less than or equal to the vehicle body speed threshold value, the turning radius is not so small even if a substantially equal braking force is applied to each wheel. When the absolute value of the steering angle is not less than the steering angle threshold and the steering torque is not less than the torque threshold, the braking control during turning is executed.

  According to a third aspect of the present invention, in the vehicle braking control device according to the first or second aspect, the control means (S19) applies a braking force to each wheel (FR, FL, RR, RL) ( The gist of the present invention is to stop execution of the braking control during turning when the braking force applying means (37) operated when applying (BP) is operated.

  In the above configuration, when the braking force applying means is operated, the braking force is applied to the outer wheel and the inner wheel in the turning direction of the vehicle, so the turning braking control is not executed. Therefore, an increase in load on the actuator driven to apply a great braking force to the wheels on the inner side in the turning direction and the wheels on the inner side in the turning direction of the vehicle is suppressed.

  According to a fourth aspect of the present invention, in the vehicle braking control device according to the first or second aspect, the control means (S19) applies a braking force (F, FL, RR, RL) to the wheels (FR, FL, RR, RL). When the braking force applying means (37) operated when applying (BP) is operated, the wheel (RR) on the inner side in the turning direction than the wheel (FL, RL) on the outer side in the turning direction of the vehicle (C) is operated. The gist is to execute the braking control during turning so that a large braking force (BP) is applied.

  In the above configuration, when the braking force applying means is operated, a larger braking force is applied to the wheel on the inner side in the turning direction than the wheel on the outer side in the turning direction. Therefore, even when a braking force is applied to each wheel, the turning radius of the vehicle can be made smaller by executing the braking control during turning than when the braking control during turning is not executed. .

  According to a fifth aspect of the present invention, in the vehicle braking control device according to any one of the first to fourth aspects, the control means (S19) is calculated by the steering torque calculating means (S15). The gist is to execute the braking control during turning so that the larger the steering torque (T) is, the greater the braking force (BP) is applied to the wheel (RR) inside the turning direction of the vehicle (C). To do.

  In the above configuration, the magnitude of the braking force applied to the wheel on the inner side in the turning direction of the vehicle is adjusted in accordance with the steering torque applied to the steering by the driver. Therefore, it becomes possible to execute vehicle turning control in accordance with the driver's intention.

  On the other hand, the invention according to claim 6 relating to the vehicle braking control method is the braking force (BP) applied to the wheels (FR, FL, RR, RL) disposed on the left and right sides with respect to the traveling direction of the vehicle (C). ), The steering angle (A) of the steering (24) of the vehicle (C) and the steering torque (T) applied to the steering (24) are calculated, When the absolute value of the calculated steering angle (A) is greater than or equal to a preset steering angle threshold (KA), the calculated steering torque (T) is greater than or equal to a preset torque threshold (KT). At a certain point, the gist is that the braking control during turning for applying the braking force (BP) to the wheel (RR) inside the turning direction of the vehicle (C) is executed.

  With the above configuration, the same effect as that of the first aspect of the invention can be achieved.

  DESCRIPTION OF EXEMPLARY EMBODIMENTS Hereinafter, an embodiment of a vehicle braking control device and a vehicle braking control method according to the 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). Unless otherwise specified, the left-right direction in the following description is the same as the left-right direction in the vehicle traveling direction.

  As shown in FIG. 1, the vehicle braking control device 11 according to the present embodiment includes a plurality of (four in the present embodiment) wheels (right front wheel FR, left front wheel FL, right rear wheel RR, and left rear wheel RL). Of these, the front wheels FR and FL are mounted on a vehicle (so-called front wheel drive vehicle) that functions as drive wheels. This vehicle includes a driving force transmission mechanism 13 that transmits driving force generated by an engine 12 serving as a driving source to front wheels FR and FL, and front wheel steering for turning the front wheels FR and FL as steered wheels (steering wheels). A mechanism 14 and a braking force application mechanism 15 for applying a braking force to each wheel FL, FR, RL, RR are provided. In addition, the vehicle includes an electronic control device (hereinafter referred to as “ECU”) 16 for appropriately controlling the mechanisms 13, 14, and 15 according to the traveling state of the vehicle. The apparatus 11 is comprised. The engine 12 generates a driving force corresponding to the depression operation of the accelerator pedal 17 by the driver of the vehicle.

  The driving force transmission mechanism 13 is provided with a transmission 18 connected to the output shaft of the engine 12 and a front wheel differential gear 19 for appropriately distributing the driving force transmitted from the transmission 18 and transmitting it to the front wheels FL and FR. It has been. An intake passage 20a in the intake pipe 20 extending outward from the engine 12 is provided with a throttle valve 21 for varying the opening cross-sectional area, and outside the intake pipe 20, a throttle valve 21 is provided. A throttle valve actuator (for example, a DC motor) 22 for controlling the opening is provided. A fuel injection device 23 having an injector for injecting fuel is provided in the vicinity of an intake port (not shown) of the engine 12. In the vicinity of the accelerator pedal 17, an accelerator opening sensor SE1 is provided for detecting the amount of depression (opening) of the accelerator pedal 17 by the driver.

  The front wheel steering mechanism 14 is provided with a steering wheel 24, a steering shaft 25 to which the steering wheel 24 is fixed, and a steering actuator 26 connected to the steering shaft 25. The front wheel steering mechanism 14 includes a tie rod 27 that includes a tie rod that can be moved in the left-right direction of the vehicle by a steering actuator 26 and a link that steers the front wheels FL and FR by the movement of the tie rod. Is provided. Further, the front wheel steering mechanism 14 is provided with a steering angle sensor SE2 for detecting the steering angle of the steering wheel 24 and a steering torque sensor SE3 for detecting the steering torque applied to the steering wheel 24.

Next, the braking force application mechanism 15 will be described with reference to FIG.
As shown in FIG. 2, the braking force applying mechanism 15 of the present embodiment includes a hydraulic pressure generating device 32 having a master cylinder 30 and a booster 31, and a hydraulic pressure control device having two hydraulic pressure circuits 33 and 34 (FIG. 2). Is shown by a two-dot chain line). The hydraulic circuits 33 and 34 are connected to the hydraulic pressure generator 32 and are connected to wheel cylinders 36a, 36b, 36c, and 36d provided corresponding to the wheels FR, FL, RR, and RL. . That is, the wheel cylinder 36a corresponds to the right front wheel FR, and the wheel cylinder 36b corresponds to the left front wheel FL. Further, the wheel cylinder 36c corresponds to the right rear wheel RR, and the wheel cylinder 36d corresponds to the left rear wheel RL.

  The hydraulic pressure generating device 32 is provided with a brake pedal 37 as a braking force applying means, and the brake pedal 37 is depressed by a driver of the vehicle, so that the master cylinder 30 of the hydraulic pressure generating device 32 and The booster 31 is driven. The master cylinder 30 is provided with two output ports 30a and 30b. The first hydraulic circuit 33 is connected to the output port 30a, and the second hydraulic circuit 34 is connected to the output port 30b. Further, the hydraulic pressure generating device 32 is provided with a brake switch SW1 electrically connected to the ECU 16, and a signal corresponding to the operation state of the brake pedal 37 is output from the brake switch SW1 to the ECU 16.

  The hydraulic pressure control device 35 includes a pump 38 for increasing the brake hydraulic pressure in the first hydraulic pressure circuit 33, a pump 39 for increasing the brake hydraulic pressure in the second hydraulic pressure circuit 34, and each pump. A motor M for driving the motors 38 and 39 at the same time is provided. In addition, reservoirs 40 and 41 for storing brake fluid are provided on the hydraulic circuits 33 and 34, and the brake fluid in the reservoirs 40 and 41 is driven by the pumps 38 and 39. , 34 are supplied.

  The first hydraulic circuit 33 includes a left front wheel path 33a for the wheel cylinder 36b (for the left front wheel FL) connected to the wheel cylinder 36b corresponding to the left front wheel FL, and a wheel cylinder 36c corresponding to the right rear wheel RR. And a right rear wheel path 33b for the wheel cylinder 36c (for the right rear wheel RR) connected to the. On each of the paths 33a and 33b, normally open electromagnetic valves 42 and 43 and normally closed electromagnetic valves 46 and 47 are provided, respectively.

  Similarly, the second hydraulic circuit 34 corresponds to the right front wheel path 34a for the wheel cylinder 36a (for the right front wheel FR) connected to the wheel cylinder 36a corresponding to the right front wheel FR, and the left rear wheel RL. A left rear wheel path 34b for the wheel cylinder 36d (for the left rear wheel RL) connected to the wheel cylinder 36d is formed. On each of the paths 34a and 34b, normally open solenoid valves 44 and 45 and normally closed solenoid valves 48 and 49 are provided, respectively.

  In addition, a normally open proportional solenoid valve 50 is connected to the master cylinder 30 side of the first hydraulic circuit 33 with respect to the portions branched into the paths 33a and 33b, and in parallel with the proportional solenoid valve 50. A relief valve 51 is connected. The proportional solenoid valve 50 and the relief valve 51 constitute a proportional differential pressure valve 52. The proportional differential pressure valve 52 can generate a hydraulic pressure difference (brake hydraulic pressure difference) on the master cylinder 30 side and the wheel cylinders 36b and 36c side from the proportional differential pressure valve 52 based on control by the ECU 16. Note that the maximum value of the hydraulic pressure difference is a value based on the urging force of the spring 51 a constituting the relief valve 51. Further, the first hydraulic circuit 33 is formed with a branch hydraulic pressure path 33c branched from the reservoir 40 and the pump 38 toward the master cylinder 30 side, and on the branch hydraulic pressure path 33c, A normally closed electromagnetic valve 53 is connected.

  Similarly, a normally open proportional solenoid valve 54 is connected to the master cylinder 30 side of the second hydraulic circuit 34 that is branched to the paths 34 a and 34 b, and in parallel with the proportional solenoid valve 54. A relief valve 55 is connected. The proportional solenoid valve 54 and the relief valve 55 constitute a proportional differential pressure valve 56. The proportional differential pressure valve 56 can generate a hydraulic pressure difference (brake hydraulic pressure difference) between the master cylinder 30 side and the wheel cylinders 36a and 36d side with respect to the proportional differential pressure valve 56 based on control by the ECU 16. Note that the maximum value of the hydraulic pressure difference is a value based on the urging force of the spring 55a constituting the relief valve 55. Further, the second hydraulic pressure circuit 34 is formed with a branch hydraulic pressure path 34c branched from the reservoir 41 and the pump 39 toward the master cylinder 30 side, and on the branch hydraulic pressure path 34c. A normally closed electromagnetic valve 57 is connected.

  Here, changes in the brake fluid pressure in the wheel cylinders 36a to 36d when the solenoid coils of the solenoid valves 42 to 49 are in an energized state and in a non-energized state will be described. In the following description, it is assumed that the proportional solenoid valves 50 and 54 are in a closed state and the solenoid valves 53 and 57 on the branch hydraulic pressure paths 33c and 34c are in a closed state.

  First, when all the solenoid coils of the solenoid valves 42 to 49 are in a non-energized state, the normally open solenoid valves 42 to 45 remain open and the normally closed solenoid valves 46 to 49 It remains closed. Therefore, when the pumps 38 and 39 are driven, the brake fluid in the reservoirs 40 and 41 flows into the wheel cylinders 36a to 36d via the paths 33a, 33b, 34a and 34b, and the wheels The brake fluid pressure in the cylinders 36a to 36d will increase.

  On the other hand, when only the solenoid coils of the normally open solenoid valves 42 to 45 among the solenoid valves 42 to 49 are energized, all the solenoid valves 42 to 49 are closed. Therefore, the flow of brake fluid through each path 33a, 33b, 34a, 34b is restricted, so that the brake fluid pressure in each wheel cylinder 36a-36d is maintained at its fluid pressure level.

  When all the solenoid coils of the solenoid valves 42 to 49 are energized, the normally open solenoid valves 42 to 45 are closed and the normally closed solenoid valves 46 to 49 are opened. Become. Therefore, the brake fluid flows out from the wheel cylinders 36a to 36d to the reservoirs 40 and 41 through the paths 33a, 33b, 34a and 34b, and the brake fluid pressure in the wheel cylinders 36a to 36d drops. Become.

  As shown in FIG. 1, the ECU 16 mainly includes a digital computer including a CPU 60, a ROM 61, a RAM 62, and the like, and a drive circuit (not shown) for driving each device. In the ROM 61, various control programs for controlling the driving force transmission mechanism 13, the front wheel steering mechanism 14, and the braking force application mechanism 15 (hydraulic pressure control device), various maps (such as the map shown in FIG. 3), and Various threshold values (a vehicle body speed threshold value, a steering angle threshold value, a torque threshold value, etc. described later) are stored. The RAM 62 stores various information that can be appropriately rewritten while the vehicle is being driven.

  Further, the input side interface (not shown) of the ECU 16 detects the wheel speeds of the brake switch SW1, the accelerator opening sensor SE1, the steering angle sensor SE2, the steering torque sensor SE3, and the wheels FR, FL, RR, and RL. Wheel speed sensors SE4, SE5, SE6, and SE7 are connected. The steering angle sensor SE2 outputs a signal indicating that the ECU 16 indicates a positive value when the steering wheel 24 is steered to the right in the rotational direction, while the ECU 16 is negative when the steering wheel 24 is steered to the left in the rotational direction. It is set to output a signal indicating the value of.

  On the other hand, an output side interface (not shown) of the ECU 16 is connected to a motor M for driving the pumps 38 and 39, the solenoid valves 42 to 49, 53 and 57, and the proportional solenoid valves 50 and 54. The ECU 16 individually controls the operation of the motor M, the solenoid valves 42 to 49, 53, 57 and the proportional solenoid valves 50, 54 based on the input signals from the brake switch SW1 and the various sensors SE1 to SE7. It has become.

Next, the map stored in the ROM 61 will be described with reference to FIG.
The map shown in FIG. 3 shows the steering torque T applied to the steering wheel 24 and the amount of increase in the brake hydraulic pressure BP in the wheel cylinder of the rear wheel inside the turning direction of the vehicle when executing the braking control during turning described later. It shows the relationship. Specifically, when the steering torque T is less than the torque threshold value KT, the brake fluid pressure BP is not increased in the wheel cylinder of the rear wheel inside the turning direction of the vehicle. That is, the turning braking control is not executed. On the other hand, when the steering torque T is equal to or greater than the torque threshold value KT, the increase amount “BP1” of the brake hydraulic pressure BP in the wheel cylinder of the rear wheel on the inner side in the turning direction of the vehicle is larger than the steering torque T (= “T1”). It is set to increase in proportion to the height.

  Next, the turning-time braking control execution determination processing routine executed by the ECU 16 of the present embodiment will be described with reference to a flowchart shown in FIG. 4, timing charts shown in FIGS. 5 (a), 5 (b) and 5 (c) and a schematic diagram shown in FIG. This will be described below.

  The ECU 16 executes a turning braking control execution determination processing routine at predetermined intervals (for example, every “0.01” seconds). In this turning braking control execution determination processing routine, the ECU 16 determines whether or not the input signal from the brake switch SW1 is “OFF” (step S10). That is, the ECU 16 determines whether or not the brake pedal 37 is not depressed. If the determination result in step S10 is negative (SW1 = “ON”), the ECU 16 proceeds to step S17 described later.

  On the other hand, when the determination result of step S10 is affirmative (SW1 = “OFF”), the ECU 16 determines the vehicle body speed VS based on the input signals from the wheel speed sensors SE4 to SE7 of the wheels FR, FL, RR, RL. Detection is performed by calculation (step S11). That is, the ECU 16 detects the wheel speeds of the front wheels FR and FL by calculation based on the input signals from the wheel speed sensors SE4 and SE5 for the front wheels FR and FL, which are drive wheels, respectively, and the wheels of the front wheels FR and FL. The larger value of the speeds is set as the vehicle body speed VS. In this regard, in the present embodiment, the ECU 16 also functions as a vehicle body speed calculation unit.

  Then, the ECU 16 determines whether or not the vehicle body speed VS detected in step S11 is equal to or less than a preset vehicle body speed threshold value KVS (for example, “10 km / hour”) (step S12). The vehicle body speed threshold value KVS is a limit value of the vehicle body speed at which the effect of braking control during turning described later can be satisfactorily confirmed, and is set in advance to a value larger than “0 (zero)” through experiments or simulations. .

  If the determination result in step S12 is negative (VS absolute value> KVS), the ECU 16 proceeds to step S17 described later. On the other hand, if the determination result in step S12 is affirmative (VS absolute value ≦ KVS), the ECU 16 detects the steering angle A of the steering wheel 24 by the driver based on the input signal from the steering angle sensor SE2. (Step S13). In this regard, in the present embodiment, the ECU 16 also functions as a steering angle calculation unit.

  Subsequently, the ECU 16 determines whether or not the absolute value of the steering angle A detected in step S13 is equal to or greater than a preset steering angle threshold KA (step S14). This steering angle threshold KA is set to the absolute value of the maximum steering angle of the steering wheel 24 of the present embodiment. The maximum steering angle means a state in which the steering wheel 24 is steered to the maximum in a certain direction (right side or left side in the rotation direction).

  If the determination result in step S14 is negative (A absolute value <KA), the ECU 16 proceeds to step S17 described later. On the other hand, if the determination result in step S14 is affirmative (A absolute value ≧ KA), the ECU 16 determines the steering torque T applied to the steering wheel 24 by the driver based on the input signal from the steering torque sensor SE3. Detection is performed by calculation (step S15). That is, the ECU 16 detects the steering torque T when the steering angle A of the steering wheel 24 is the maximum steering angle. Therefore, in this point, in this embodiment, the ECU 16 also functions as a steering torque calculation unit.

  Subsequently, the ECU 16 determines whether or not the steering torque T detected in step S15 is equal to or greater than a preset torque threshold value KT (step S16). That is, in the present embodiment, the ECU 16 determines whether or not the steering torque T applied to the steering wheel 24 is equal to or greater than the torque threshold KT in a state where the steering angle A of the steering wheel 24 is the maximum steering angle. If the determination result in step S16 is negative (T <KT), the ECU 16 proceeds to step S17 described later.

  In step S17, the ECU 16 stops turning braking control, which will be described later, and thereafter ends the turning braking control execution determination processing routine. That is, in this embodiment, the ECU 16 stops the braking control during turning when any one of the determination processes in steps S10, S12, S14, and S16 is negative.

  On the other hand, if the determination result in step S16 is affirmative (T ≧ KT), the ECU 16 determines whether the vehicle is turning right or left from the steering angle A detected in step S13. The increase amount of the brake hydraulic pressure BP in the wheel cylinder of the rear wheel (for example, the right rear wheel RR) inside the turning direction is detected (step S18). Specifically, the ECU 16 detects the increase amount of the brake hydraulic pressure BP corresponding to the steering torque T detected in step S15 by reading it from the map shown in FIG. Then, the ECU 16 executes the turning braking control based on the increase amount “BP1” of the brake fluid pressure BP detected in step S18 (step S19), and thereafter ends the turning braking control execution determination processing routine. Therefore, in this embodiment, in this embodiment, the ECU 16 also functions as a control unit that executes the braking control during turning when all the determination processes in steps S10, S12, S14, and S16 are affirmative.

  That is, as shown in FIGS. 5A, 5B, and 5C, the vehicle body speed VS of the vehicle is equal to or less than the vehicle body speed threshold KVS, and the absolute value of the steering angle A of the steering wheel 24 is the steering angle threshold (maximum steering). When the steering torque T applied to the steering wheel 24 is equal to or greater than the torque threshold value KT, the ECU 16 executes the turning braking control. Accordingly, the steering wheel 24 is operated until the absolute value of the steering angle A becomes equal to or higher than the steering angle threshold KA in a state where the vehicle body speed VS is equal to or lower than the vehicle speed threshold KVS. Only when the steering torque T equal to or greater than the torque threshold value KT is applied, the braking control during turning is executed. Conversely, even when the steering wheel 24 is operated until the absolute value of the steering angle A becomes equal to or greater than the steering angle threshold KA, as long as the steering torque T greater than the torque threshold KT is not applied to the steering wheel 24, The braking control during turning is not executed.

Here, the vehicle braking control method when the vehicle turns to the right will be described in detail as an example.
First, the ECU 16 closes the proportional solenoid valve 50 in order to raise the brake fluid pressure BP in the wheel cylinder 36c of the rear wheel (for example, the right rear wheel RR) inside the turning direction by “BP1”, and always The open solenoid valve 42 is closed. In addition, the ECU 16 closes the proportional solenoid valve 54 and closes the normally open solenoid valves 44 and 45. Then, the brake fluid pressure BP in the wheel cylinders 36a, 36b, and 36d for wheels other than the right rear wheel RR (the right front wheel FR, the left front wheel FL, and the left rear wheel RL) is maintained.

  In this state, the ECU 16 drives the pumps 38 and 39 by driving the motor M. Then, the brake fluid flows into the wheel cylinder 36c for the right rear wheel RR, and the brake fluid pressure BP in the wheel cylinder 36c increases (increases). When the ECU 16 determines that the brake fluid pressure BP in the wheel cylinder 36c has increased by the increased amount “BP1” detected in step S18, the ECU 16 stops the driving of the motor M and at the same time the normally open electromagnetic The valve 43 is closed. Then, the brake hydraulic pressure BP in the wheel cylinder 36c is held in a state where it is increased by the increase amount “BP1”.

  By executing the braking control during turning as described above, a braking force is applied to the right rear wheel RR, while a braking force is applied to the wheels other than the right rear wheel RR as shown in FIG. Not granted. That is, the vehicle C according to the present embodiment turns in the right direction with the braking force applied to the right rear wheel RR, and therefore turns in the right direction without applying the braking force to the right rear wheel RR. The turning radius is smaller than that of the vehicle (hereinafter referred to as “non-control vehicle”) C1. Therefore, the vehicle C of the present embodiment is more effective than the non-controlled vehicle C1 when the turning braking control is executed.

Therefore, in this embodiment, the following effects can be obtained.
(1) Even if the absolute value of the steering angle A of the steering wheel 24 is equal to or greater than the steering angle threshold KA, the steering wheel 24 is steered by the driver who intends to cause the vehicle C to execute the braking control during turning. Unless the driver applies a steering torque T equal to or greater than the torque threshold KT to the steering wheel 24, the braking control during turning is not executed. Therefore, unnecessary execution of the braking control during turning can be suppressed by steering the steering wheel 24 of the driver who does not intend to execute the braking control during turning.

  (2) Generally, when the vehicle C is turned when the value of the vehicle body speed VS of the vehicle C is larger than the vehicle body speed threshold value KVS, the driver steers the steering wheel 24 while depressing the brake pedal 37. As a result of applying substantially the same braking force to the wheels FR, FL, RR, RL, the turning radius of the vehicle can be reduced. Therefore, in this case, it is not particularly necessary for the vehicle C to execute the braking control during turning. In this respect, in the present embodiment, when the vehicle body speed VS of the vehicle C is equal to or less than the vehicle body speed threshold value KVS, even if the driver depresses the brake pedal 37, the turning radius does not become so small. Control is executed. That is, when the effect based on the execution of the braking control during turning is significant, the absolute value of the steering angle A of the steering wheel 24 is not less than the steering angle threshold KA and the steering torque T is not less than the torque threshold KT. In addition, the braking control during turning is executed. Therefore, unlike the case where the braking control at the time of turning is executed when the vehicle body speed VS is larger than the vehicle body speed threshold value KVS, the braking force is applied to the rear wheel (for example, the right rear wheel RR) inside the turning direction of the vehicle C. An increase in the load on the actuator (wheel cylinder 36c) and the load on the rear wheel (for example, the right rear wheel RR) inside the turning direction can be suppressed.

  (3) When the brake pedal (braking force applying means) 37 is depressed, braking force is applied to the outer wheel and the inner wheel in the turning direction of the vehicle C. Is not executed. Therefore, when a large braking force is applied to the inner wheel in the turning direction (for example, the right rear wheel RR), the braking force is applied to the inner wheel in the turning direction (for example, the right rear wheel RR). It is possible to suppress an increase in the loads of the actuator (wheel cylinder 36c) that is driven to the right and the wheels (for example, the right rear wheel RR) inside the turning direction.

  (4) The increase amount of the brake fluid pressure BP corresponding to the steering torque T applied to the steering wheel 24 by the driver is read from the map shown in FIG. Therefore, since the braking force suitable for the driver can be applied to the rear wheel (for example, the right rear wheel RR) on the inner side in the turning direction, the turning of the vehicle C can be made in line with the driver's intention.

  (5) Further, the control load of the ECU 16 is better than when the increase amount of the brake hydraulic pressure BP corresponding to the steering torque T is calculated from the relational expression between the steering torque T and the increase amount of the brake hydraulic pressure BP. Can be suppressed.

  (6) In the turning braking control of the present embodiment, a braking force is applied to the rear wheel (for example, the right rear wheel RR) inside the turning direction of the vehicle C. Therefore, the turning radius of the vehicle C can be made smaller and the turning of the vehicle C can be made effective compared to the case where braking force is applied to the front wheel (for example, the right front wheel FR) inside the turning direction of the vehicle C. Can do.

The embodiment may be changed to another embodiment as described below.
In the embodiment, when the braking control during turning is executed, the increase amount of the brake hydraulic pressure BP in the wheel cylinder at the rear wheel inside the turning direction of the vehicle C is made uniform regardless of the magnitude of the steering torque T. Also good. Further, the increase amount of the brake hydraulic pressure BP corresponding to the steering torque T may be calculated from a relational expression between the steering torque T and the increase amount of the brake hydraulic pressure BP. In the case of such a configuration, it is not necessary to set and store the map shown in FIG. 3 in the ROM 61, so that an increase in the storage amount of the ROM 61 can be suppressed.

  In the embodiment, when the brake pedal 37 is depressed by the driver, the braking force applied to the rear wheel (for example, the right rear wheel RR) on the inner side in the turning direction of the vehicle C is set to other wheels (for example, the right front wheel FR). The braking force for the left front wheel FL and the left rear wheel RL) may be larger. In such a configuration, the brake pedal 37 is depressed by the driver, so that even when braking force is applied to the wheels FR, FL, RR, RL, the braking control during turning is executed. The turning radius of the vehicle C can be made smaller than when the braking control during turning is not executed.

  -In embodiment, it is not necessary to perform the determination process of step S12 of the braking control execution determination process routine at the time of turning. In other words, regardless of the vehicle body speed VS of the vehicle C, when all the determination processes in steps S10, S14, and S16 are affirmative determinations, the braking control during turning may be executed.

  -In embodiment, when performing braking control at the time of turning, you may make it provide braking force also to the front wheel inside the turning direction of the vehicle C. FIG. Alternatively, the braking force may be applied only to the front wheel inside the turning direction without applying the braking force to the rear wheel inside the turning direction of the vehicle C.

In the embodiment, the steering angle threshold KA may be a value smaller than the maximum steering angle.
In the embodiment, instead of the brake control device 11 mounted on the front wheel drive vehicle, the embodiment may be embodied in a brake control device mounted on the rear wheel drive vehicle, or may be applied to a brake control device mounted on the four wheel drive vehicle. It may be embodied.

  In the embodiment, the first hydraulic circuit 33 is connected to the wheel cylinder 36a for the right front wheel FR and the wheel cylinder 36b for the left front wheel FL, and the second hydraulic circuit 34 is for the right rear wheel RR. The wheel cylinder 36c and the wheel cylinder 36d for the left rear wheel RL may be connected to each other.

  In the embodiment, the braking force applying mechanism 15 converts the operation amount of the brake pedal 37 by the driver of the vehicle into an electric signal, and applies the braking force based on the electric signal to each wheel FR, FL, RR, RL. The so-called brake-by-wire method may be used.

The block diagram of the vehicle by which the braking control apparatus of this embodiment is mounted. The block diagram of the braking force provision mechanism in this embodiment. The map which shows the relationship between the steering torque added to a steering wheel, and the increase amount of the brake fluid pressure in the wheel cylinder of the rear wheel inside a turning direction. The flowchart which shows the braking control execution determination processing routine at the time of turning. (A) is a timing chart showing a change in vehicle body speed, (b) is a timing chart showing a change in steering angle of the steering wheel, and (c) is a timing chart showing a change in steering torque applied to the steering wheel. The schematic diagram shown in the state which compared the mode that the vehicle is turning in the state in which the braking control at the time of turning was performed, and the state in which the vehicle is turning in the state in which the braking control at the time of turning is not executed.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 11 ... Brake control apparatus of vehicle, 16 ... ECU (steering angle calculating means, steering torque calculating means, control means, vehicle body speed calculating means), 24 ... Steering wheel, 37 ... Brake pedal (braking force applying means), A ... Steering Angle, BP ... Brake hydraulic pressure (braking force), C ... Vehicle, FR ... Right front wheel, FL ... Left front wheel (wheel outside the turning direction of the vehicle), KA ... Steering angle threshold, KT ... Torque threshold, KVS ... Body speed Threshold value: RR ... Right rear wheel (wheel inside vehicle turning direction), RL ... Left rear wheel (wheel outside vehicle turning direction), T ... steering torque, VS ... body speed.

Claims (6)

It is mounted on a vehicle (C) in which wheels (FR, FL, RR, RL) are arranged on both the left and right sides with respect to the traveling direction of the vehicle (C), and is applied to each wheel (FR, FL, RR, RL). In the braking control device (11) of the vehicle (C) that controls the power (BP),
Steering angle calculation means (S13) for calculating the steering angle (A) of the steering (24) of the vehicle (C);
Steering torque calculating means (S15) for calculating a steering torque (T) applied to the steering (24);
The absolute value of the steering angle (A) calculated by the steering angle calculation means (S13) is not less than a preset steering angle threshold value (KA), and the calculation is performed by the steering torque calculation means (S15). When the steering torque (T) is equal to or greater than a preset torque threshold value (KT), the braking control during turning is performed in which the braking force (BP) is applied to the wheel (RR) inside the turning direction of the vehicle (C). A braking control device for a vehicle comprising control means (S19). Vehicle speed calculation means (S11) for calculating the vehicle speed (VS) of the vehicle (C),
The control means (S19) executes the braking control during turning when the vehicle body speed (VS) calculated by the vehicle body speed calculation means (S11) is not more than a preset vehicle body speed threshold (KVS). The vehicle braking control device according to claim 1. The control means (S19) performs the turning when the braking force applying means (37) operated when applying the braking force (BP) to each wheel (FR, FL, RR, RL) is operated. The vehicle braking control device according to claim 1 or 2, wherein execution of the hourly braking control is stopped. When the braking force applying means (37) operated when applying the braking force (BP) to each wheel (FR, FL, RR, RL) is operated, the control means (S19) The braking control during turning is executed so that a larger braking force (BP) is applied to the wheel (RR) inside the turning direction than the wheel (FL, RL) outside the turning direction of C). 3. A braking control device for a vehicle according to 2. The control means (S19) increases the braking force (BP) on the wheel (RR) on the inner side in the turning direction of the vehicle (C) as the steering torque (T) calculated by the steering torque calculation means (S15) increases. The braking control device for a vehicle according to any one of claims 1 to 4, wherein the turning braking control is executed such that the braking control is performed. In the braking control method of the vehicle (C) for controlling the braking force (BP) applied to the wheels (FR, FL, RR, RL) disposed on the left and right sides with respect to the traveling direction of the vehicle (C),
The steering angle (A) of the steering (24) of the vehicle (C) is calculated, the steering torque (T) applied to the steering (24) is calculated, and the absolute value of the calculated steering angle (A) is calculated in advance. When the calculated steering torque (T) is equal to or greater than a preset torque threshold (KT) when the calculated steering angle threshold (KA) is greater than or equal to the set steering angle threshold (KA), the vehicle (C) is turned inward in the turning direction. A braking control method for a vehicle in which turning braking control for applying braking force (BP) to (RR) is executed.

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