JP2010195170A - Braking control device for vehicle - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a braking control device for a vehicle capable of suppressing deviation of motion of brake pedal reaction force relative to motion of a brake pedal and reducing incompatible sense given to a driver. <P>SOLUTION: Flow passage resistance of brake circuits 10l, 10m, 20l, 20m is increased by increasing a valve closure amount Vpo of pressure-increase valves 12, 13, 22, 23 as the detected stroke speed ΔXi of an input rod 6 is high. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a vehicle brake control device including a brake booster.

  In the brake booster described in Patent Document 1, the target piston stroke is calculated according to the stroke of the input rod that moves forward and backward integrally with the brake pedal, and the actuator of the brake booster is set so that the piston stroke becomes the target piston stroke. And thrust is applied to the piston.

JP 2007-112426 A

  However, the conventional technology has a problem that when the driver depresses the brake pedal, the brake pedal reaction force rises with a delay in response to the pedal operation due to the response delay of the actuator, which gives the driver an uncomfortable feeling.

  An object of the present invention is to provide a vehicular braking control device that can suppress a shift in the movement of a brake pedal reaction force with respect to a movement of a brake pedal and reduce a sense of discomfort given to a driver.

  In order to solve the above problems, in the present invention, when it is determined that the vehicle is stopped, the higher the moving speed of the input member that moves forward and backward by operating the brake pedal, the higher the flow of the brake circuit that connects the master cylinder and each wheel cylinder. Increase road resistance.

  Therefore, in this invention, the shift | offset | difference of the motion of the brake pedal reaction force with respect to the motion of a brake pedal can be suppressed, and the discomfort given to a driver can be reduced.

1 is an overall configuration diagram of a brake device 1 according to a first embodiment. FIG. 3 is a control block diagram of a master cylinder pressure control device 8 according to the first embodiment. 3 is a flowchart showing a flow of valve closing amount adjustment processing by a master cylinder pressure control device 8 of Embodiment 1. It is a figure which shows the delay of the input rod input Fi with respect to the input rod stroke Xi accompanying the response delay of the electric motor 50. FIG. 3 is a time chart illustrating the operation of the first embodiment. It is a control block diagram of the master cylinder pressure control apparatus 8 of Example 2. It is a flowchart which shows the flow of the valve closing amount adjustment process by the master cylinder pressure control apparatus 8 of Example 2. FIG. It is a flowchart which shows the flow of the vehicle stop determination process of S12. It is a flowchart which shows the flow of a stop cylinder master cylinder pressure calculation process of step S13. 6 is a time chart showing the operation of the second embodiment. FIG. 6 is a control block diagram of a master cylinder pressure control device 8 according to a third embodiment. It is a flowchart which shows the flow of the valve closing amount adjustment process performed with the master cylinder pressure control apparatus 8 of Example 3. FIG. FIG. 6 is a control block diagram of a master cylinder pressure control device 8 according to a third embodiment. 10 is a flowchart showing a flow of a valve closing amount adjustment process executed by a master cylinder pressure control device 8 according to a fourth embodiment. It is a figure which shows the effect | action of Example 4. FIG.

  EMBODIMENT OF THE INVENTION Hereinafter, the form for implementing the brake control apparatus for vehicles of this invention is demonstrated based on the Example shown on drawing.

First, the configuration will be described.
[Brake device]
FIG. 1 is an overall configuration diagram of a brake device 1 according to a first embodiment. The brake device 1 according to the first embodiment is mounted on a hybrid vehicle that uses an electric motor and an engine as power sources. In the figure, the FL wheel is the left front wheel, the FR wheel is the right front wheel, the RL wheel is the left rear wheel, and the RR wheel is the right rear wheel. A broken line with an arrow is a signal line, and a signal flow is represented by the direction of the arrow.

  The brake control device 1 is connected to the master cylinder 2, the reservoir tank RES, the wheel cylinder pressure control mechanism 3, the wheel cylinders 4 a to 4 d provided on each wheel FL, FR, RL, RR, and the master cylinder 2. A master cylinder pressure control mechanism 5 and an input rod 6, a brake operation amount detection device (movement amount detection means) 7, a master cylinder pressure control device 8 for controlling the master cylinder pressure control mechanism 5, and a wheel cylinder pressure. And a wheel cylinder pressure control device 9 for controlling the control mechanism 3.

  The input rod 6 increases and decreases the hydraulic pressure in the master cylinder 2 (hereinafter referred to as master cylinder pressure Pmc) together with the brake pedal BP. The master cylinder pressure control mechanism 5 and the master cylinder pressure control device 8 increase or decrease the master cylinder pressure Pmc together with the primary piston 2 b of the master cylinder 2.

  Hereinafter, for description, the x-axis is set in the axial direction of the master cylinder 2 and the brake pedal BP side is defined as the negative direction. The master cylinder 2 is a so-called tandem type, and has a primary piston 2b and a secondary piston 2c in a cylinder 2a. A primary liquid chamber 2d as a pressurizing chamber is formed between the inner peripheral surface of the cylinder 2a, the surface of the primary piston 2b on the x-axis positive direction side, and the surface of the secondary piston 2c on the x-axis negative direction side. . A secondary liquid chamber 2e as a pressurizing chamber is formed between the inner peripheral surface of the cylinder 2a and the surface of the secondary piston 2c on the x-axis positive direction side.

  The primary fluid chamber 2 d is connected to be able to communicate with the brake circuit 10, and the secondary fluid chamber 2 e is connected to be able to communicate with the brake circuit 20. The volume of the primary liquid chamber 2d changes as the primary piston 2b and the secondary piston 2c slide in the cylinder 2a. In the primary liquid chamber 2d, a return spring 2f that urges the primary piston 2b in the negative x-axis direction is installed. The volume of the secondary liquid chamber 2e changes as the secondary piston 2c slides in the cylinder 2a. In the secondary liquid chamber 2e, a return spring 2g that urges the secondary piston 2c to the x-axis negative direction side is installed.

  One end 6a of the input rod 6 on the x axis positive direction side passes through the partition wall 2h of the primary piston 2b and is installed in the primary liquid chamber 2d. The gap between the one end 6a of the input rod 6 and the partition wall 2h of the primary piston 2b is sealed to maintain liquid tightness, and the one end 6a is slidable in the x-axis direction with respect to the partition wall 2h. . On the other hand, the other end 6b of the input rod 6 on the negative x-axis side is connected to the brake pedal BP. When the brake pedal BP is depressed, the input rod 6 moves to the x-axis positive direction side, and when the brake pedal BP is returned, the input rod 6 moves to the x-axis negative direction side.

  The hydraulic fluid in the primary fluid chamber 2d is pressurized by the input rod 6 or the primary piston 2b (driven by the drive motor 50) propelled toward the positive x-axis direction. The pressurized hydraulic fluid is supplied to the wheel cylinder pressure control mechanism 3 via the brake circuit 10. Further, the secondary piston 2c is propelled to the x-axis positive direction side by the pressure of the pressurized primary liquid chamber 2d. The hydraulic fluid in the secondary fluid chamber 2e is pressurized by the propulsion of the secondary piston 2c and supplied to the wheel cylinder pressure control mechanism 3 via the brake circuit 20.

  In this way, the input rod 6 moves in conjunction with the brake pedal BP and pressurizes the primary fluid chamber 2d, so that even if the drive motor 50 stops due to a failure, the master cylinder pressure is controlled by the driver's brake operation. Pmc can be raised and a predetermined braking force is secured. Further, since a force corresponding to the master cylinder pressure Pmc acts on the brake pedal BP via the input rod 6 and is transmitted to the driver as a brake pedal reaction force, the brake pedal reaction force required when the above configuration is not adopted. A device such as a spring for generating the is eliminated. Therefore, the brake control device can be reduced in size and weight, and the mounting property on the vehicle is improved.

  On the other end 6 b side of the input rod 6, a brake operation amount detection device 7 that detects a driver's required braking force is provided. The brake operation amount detection device 7 is a displacement sensor (stroke sensor for the brake pedal BP) that detects the amount of displacement of the input rod 6 in the x-axis direction. In the first embodiment, two displacement sensors 7 a and 7 b are provided, and the displacement amounts detected by these sensors are respectively input to the master cylinder pressure control device 8. By combining multiple displacement sensors in this way, in the unlikely event that a signal from one sensor is interrupted due to a failure, the brake request of the driver is detected and recognized by the remaining sensors. Secured.

Further, the brake operation amount detection device 7 may have a configuration in which a pedal force sensor for detecting the pedal force of the brake pedal BP, or a combination of a stroke sensor and a pedal force sensor.
The reservoir tank RES has at least two liquid chambers separated from each other by a partition wall. Each fluid chamber is connected to the primary fluid chamber 2d and the secondary fluid chamber 2e of the master cylinder 2 through the brake circuits 10j and 20j, respectively.
The wheel cylinder pressure control mechanism 3 is a hydraulic pressure control unit capable of executing ABS control, vehicle behavior stabilization control, and the like. The hydraulic cylinder pressurized by the master cylinder 2 or the like is used as a control command for the wheel cylinder pressure control device 9. Accordingly, it is supplied to each of the wheel cylinders 4a to 4d.

  The wheel cylinders 4a to 4d have cylinders, pistons, pads, etc., and the pistons are driven by the hydraulic fluid supplied from the wheel cylinder pressure control mechanism 3, and the pads connected to the pistons are connected to the disk rotors 40a to 40a. It is a well-known thing pressed by 40d. The disc rotors 40a to 40d rotate integrally with the wheels FL, FR, RL, and RR, respectively, and the brake torque acting on the disc rotors 40a to 40d acts between the wheels FL, FR, RL, and RR and the road surface. Brake force.

The master cylinder pressure control mechanism 5 controls the displacement amount of the primary piston 2b, that is, the master cylinder pressure Pmc in accordance with the control command of the master cylinder pressure control device 8, and includes a drive motor 50, a speed reduction device 51, and rotation-translation. Conversion device 55.
The master cylinder pressure control device 8 is an arithmetic processing circuit, and operates the drive motor 50 based on sensor signals from the brake operation amount detection device 7 and the drive motor 50, signals from a wheel cylinder pressure control device 9 to be described later, and the like. To control.

The wheel cylinder pressure control device 9 is an arithmetic processing circuit that adjusts the distance from the preceding vehicle, road information, and vehicle state quantities (for example, yaw rate, longitudinal acceleration, lateral acceleration, steering angle, wheel speed, vehicle speed, etc.). Based on this, the target braking force to be generated in each wheel FL, FR, RL, RR is calculated. Based on this calculation result, the operation of each actuator (solenoid valve or pump) of the wheel cylinder pressure control mechanism 3 is controlled.
The master cylinder pressure control device 8 and the wheel cylinder pressure control device 9 are connected by a signal line L and can communicate with each other.

[Foil cylinder pressure control mechanism]
Hereinafter, the hydraulic circuit configuration of the wheel cylinder pressure control mechanism 3 will be described.
The brake circuit has two independent brake systems and is divided into a primary system and a secondary system. The primary system receives the supply of hydraulic fluid from the primary fluid chamber 2 d and controls the braking force of the FL wheel and the RR wheel via the brake circuit 10. The secondary system receives the supply of hydraulic fluid from the secondary fluid chamber 2 e and controls the braking force of the FR wheel and the RL wheel via the brake circuit 20. Thus, because of the so-called X piping structure, even when one brake system fails, the brake force for the two diagonal wheels is secured by the other normal brake system, and the behavior of the vehicle is kept stable. . Hereinafter, the primary system will be described as an example.

  On the way from the master cylinder 2 side (hereinafter referred to as upstream) of the brake circuit 10 toward the wheel cylinders 4a and 4d (hereinafter referred to as downstream), an out-side gate valve 11 is provided. The out side gate valve 11 is opened when the hydraulic fluid pressurized by the master cylinder 2 is supplied to the wheel cylinders 4a and 4d.

  The downstream side of the brake circuit 10k provided with the out-side gate valve 11 branches to brake circuits 10a and 10b, and the brake circuits 10a and 10b are connected to the wheel cylinders 4a and 4d via the brake circuits 10l and 10m, respectively. . Booster valves 12 and 13 are provided on the brake circuits 10a and 10b, respectively. The pressure increasing valves 12 and 13 are opened when supplying hydraulic fluid pressurized by the master cylinder 2 or a pump P described later to the wheel cylinders 4a and 4d.

  Return circuits 10c and 10d are connected to the brake circuits 10a and 10b on the downstream side of the pressure increasing valves 12 and 13, respectively. Pressure reducing valves 14 and 15 are provided on the return circuits 10c and 10d, respectively. The pressure reducing valves 14 and 15 are opened when the pressure in the wheel cylinders 4a and 4d (hereinafter referred to as wheel cylinder pressure Pwc) is reduced. The return circuits 10 c and 10 d join together to form a return circuit 10 e, and the return circuit 10 e is connected to the reservoir 16.

  On the other hand, the brake circuit 10 branches upstream of the out-side gate valve 11 to form a suction circuit 10g. On the suction circuit 10g, an in-side gate valve 17 for switching communication / blocking of the suction circuit 10g is provided. The in-side gate valve 17 is opened, for example, when the hydraulic fluid pressurized by the master cylinder 2 is pressurized by a pump P described later and supplied to the wheel cylinders 4a and 4d. The suction circuit 10g joins with the return circuit 10f from the reservoir 16 to form a suction circuit 10h.

  The brake circuit 10 is connected to a pump P for sucking and discharging hydraulic fluid as a hydraulic pressure source other than the master cylinder 2. The pump P is a plunger type or gear type pump, and includes a first pump P1 and a second pump P2. For example, when automatic brake control such as vehicle behavior stabilization control is performed, the pump P boosts the master cylinder pressure Pmc and supplies it to the wheel cylinders 4a and 4d when pressure exceeding the operating pressure of the master cylinder 2 is required. To do. The first pump P1 is connected to the suction circuit 10h and the discharge circuit 10i, and is connected to the brake circuit 10k via the discharge circuit 10i.

The motor M is a DC (direct current) brushless motor or a DC brush motor, and pumps P1 and P2 are connected to its output shaft. The motor M is operated by the electric power supplied based on the control command of the wheel cylinder pressure control device 9, and drives the pumps P1 and P2.
The out-side gate valve 11, the in-side gate valve 17, the pressure-increasing valves 12 and 13, and the pressure-reducing valves 14 and 15 are electromagnetic type valves that are opened and closed by energizing the solenoid, and the wheel cylinder pressure control device 9. When a drive current having a magnitude corresponding to the drive signal output from is supplied, the opening / closing amount of the valve is individually controlled.

The out-side gate valve 11 and the pressure increasing valves 12 and 13 are normally open valves, and the in-side gate valve 17 and the pressure reducing valves 14 and 15 are normally closed valves. As a result, even if the power supply to one of the valves is stopped due to a failure, the hydraulic fluid pressurized by the master cylinder 2 all reaches the wheel cylinders 4a and 4d. Brake force as required by the driver can be generated.
The hydraulic circuit on the brake circuit 20 side is configured similarly to the brake circuit 10 side.

  In the brake circuit 10 (between the master cylinder 2 and the wheel cylinder pressure control mechanism 3) and the brake circuit 20 (in the wheel cylinder pressure control mechanism 3), the master cylinder pressure Pmc (primary fluid chamber 2d and secondary fluid chamber, respectively). Master cylinder pressure sensors (master cylinder pressure detecting means) 3a and 3b, which are pressure sensors for detecting the pressure 2e) are provided. Information on the master cylinder pressure Pmc detected by the master cylinder pressure sensors 3 a and 3 b is input to the master cylinder pressure control device 8 and the wheel cylinder pressure control device 9. Note that the number and installation positions of the master cylinder pressure sensors can be arbitrarily determined in consideration of controllability, fail-safety, and the like.

Hereinafter, the operation of the wheel cylinder pressure control mechanism 3 during brake control will be described.
During normal control, the hydraulic fluid in the master cylinder 2 is supplied to the wheel cylinders 4a to 4d via the brake circuits 10 and 20, and a braking force is generated.
At the time of ABS control, taking the wheel FL as an example, the pressure reducing valve 14 connected to the wheel cylinder 4 a is opened, the pressure increasing valve 12 is closed, and the hydraulic fluid in the wheel cylinder 4 a is returned to the reservoir 16 to reduce the pressure. I do. Further, when the wheel FL recovers from the locking tendency, the pressure increase is performed by opening the pressure increasing valve 12 and closing the pressure reducing valve 14. At this time, the pump P returns the hydraulic fluid released to the reservoir 16 to the brake circuit 10k.

  During automatic brake control such as vehicle behavior stabilization control, the out-side gate valves 11 and 21 are closed while the in-side gate valves 17 and 27 are opened. At the same time, the pump P is operated to discharge the hydraulic fluid from the master cylinder 2 toward the brake circuits 10k and 20k via the suction circuits 10g, 10h, 20g and 20h and the discharge circuits 10i and 20i. Further, the out-side gate valves 11 and 21 or the pressure increasing valves 12, 13, 22, and 23 are controlled so that the wheel cylinder pressure Pwc becomes a target pressure corresponding to the required braking force.

[Master cylinder pressure control mechanism]
Hereinafter, the configuration and operation of the master cylinder pressure control mechanism 5 will be described. The drive motor 50 is a three-phase DC brushless motor, and operates with electric power supplied based on a control command of the master cylinder pressure control device 8 to generate a desired rotational torque.

  The reduction gear 51 decelerates the output rotation of the drive motor 50 by a pulley deceleration method. The reduction gear 51 includes a small-diameter driving pulley 52 provided on the output shaft of the driving motor 50, a large-diameter driven pulley 53 provided on the ball screw nut 56 of the rotation-translation converter 55, the driving side and the driven And a belt 54 wound around the side pulleys 52 and 53. The reduction gear 51 amplifies the rotational torque of the drive motor 50 by the reduction ratio (radial ratio between the drive side and driven pulleys 52 and 53) and transmits the amplified torque to the rotation-translation conversion device 55.

  If the rotational torque of the drive motor 50 is sufficiently large and torque amplification by deceleration is not necessary, the reduction gear 51 may be omitted and the drive motor 50 and the rotation-translation conversion device 55 may be directly connected. . In this case, it is possible to avoid various problems relating to reliability, quietness, and mountability caused by the intervention of the reduction gear 51.

  The rotation-translation converter 55 converts the rotational power of the drive motor 50 into translation power, and presses the primary piston 2b with this translation power. In the first embodiment, a ball screw system is adopted as the power conversion mechanism, and the rotation-translation conversion device 55 includes a ball screw nut 56, a ball screw shaft 57, a movable member 58, and a return spring 59. Yes.

  A first housing member HSG1 is connected to the x-axis negative direction side of the master cylinder 2, and a second housing member HSG2 is connected to the x-axis negative direction side of the first housing member HSG1. The ball screw nut 56 is installed on the inner periphery of the bearing BRG provided in the second housing member HSG2 so as to be rotatable. A driven pulley 53 is fitted to the outer periphery of the ball screw nut 56 on the x-axis negative direction side. A hollow ball screw shaft 57 is screwed into the inner periphery of the ball screw nut 56. A plurality of balls are rotatably installed in the gap between the ball screw nut 56 and the ball screw shaft 57.

  A movable member 58 is integrally provided at the end of the ball screw shaft 57 on the positive side in the x-axis direction. The primary piston 2b is joined to the surface of the movable member 58 on the x-axis positive direction side. The primary piston 2b is accommodated in the first housing member HSG1. The x-axis positive direction end of the primary piston 2b protrudes from the first housing member HSG1 and is fitted to the inner periphery of the cylinder 2a of the master cylinder 2.

  In the first housing member HSG1, a return spring 59 is provided on the outer periphery of the primary piston 2b. The end of the return spring 59 on the x-axis positive direction side is fixed to the surface A on the x-axis positive direction side inside the first housing member HSG1, while the end of the x-axis negative direction side is engaged with the movable member 58. . The return spring 59 is installed to be compressed in the x-axis direction between the surface A and the movable member 28, and biases the movable member 58 and the ball screw shaft 57 in the negative x-axis direction.

  When the driven pulley 53 rotates, the ball screw nut 56 rotates together, and the ball screw shaft 57 translates in the x-axis direction by the rotational movement of the ball screw nut 56. The primary piston 2b is pressed to the positive x-axis direction via the movable member 58 by the thrust of the translational motion of the ball screw shaft 57 toward the positive x-axis direction. FIG. 1 shows a state in which the ball screw shaft 57 is at the initial position where the ball screw shaft 57 is displaced maximum in the negative x-axis direction when the brake is not operated.

  On the other hand, the elastic force of the return spring 59 acts on the ball screw shaft 57 in the direction opposite to the thrust in the positive x-axis direction (the negative x-axis direction). As a result, during braking, that is, in the state where the primary piston 2b is pressed in the positive direction of the x axis and the master cylinder pressure Pmc is increased, the drive motor 50 stops due to a failure and the return control of the ball screw shaft 57 is performed. Even when it becomes impossible, the ball screw shaft 27 is returned to the initial position by the reaction force of the return spring 59. As a result, the master cylinder pressure Pmc decreases to near zero, so that the occurrence of dragging of the braking force is prevented, and the situation where the vehicle behavior becomes unstable due to this dragging is avoided.

  A pair of springs 6d and 6e (biasing means) are disposed in the annular space B defined between the input rod 6 and the primary piston 2b. One end of each of the pair of springs 6d and 6e is locked to a flange portion 6c provided on the input rod 6, the other end of the spring 6d is locked to a partition wall 2h of the primary piston 2b, and the other end of the spring 6e is It is locked to the partition wall 2i of the primary piston 2b. The pair of springs 6d and 6e bias the input rod 6 toward the neutral position of the relative displacement of the primary piston 2b, and the neutral position of the relative movement of the input rod 6 and the primary piston 2b when the brake is not operated. It has a function to hold. When the input rod 6 and the primary piston 2b are relatively displaced in either direction from the neutral position, a biasing force that returns the input rod 6 to the neutral position acts on the primary piston 2b by the pair of springs 6d and 6e. To do.

The drive motor 50 is provided with a rotation angle detection sensor 50a, and a position signal of the motor output shaft detected thereby is input to the master cylinder pressure control device 8. The master cylinder pressure control device 8 calculates the rotation angle of the drive motor 50 based on the input position signal, and based on this rotation angle, the propulsion amount of the rotation-translation conversion device 25, that is, the displacement amount of the primary piston 2b in the x-axis direction. Is calculated.
The drive motor 50 is provided with a temperature sensor 50 b, and detected temperature information of the drive motor 50 is input to the master cylinder pressure control device 8.

[Boost control processing]
Next, the amplifying action of the thrust of the input rod 6 by the master cylinder pressure control mechanism 5 and the master cylinder pressure control device 8 will be described.
The master cylinder pressure control mechanism 5 and the master cylinder pressure control device 8 displace the primary piston 2b according to the amount of displacement of the input rod 6 caused by the driver's brake operation. As a result, the primary fluid chamber 2d is pressurized by the thrust of the primary piston 2b in addition to the thrust of the input rod 6, and the master cylinder pressure Pmc is adjusted. That is, the thrust of the input rod 6 is amplified. The amplification ratio (hereinafter referred to as boost ratio α) is determined as follows according to the ratio of the axial cross-sectional areas (hereinafter referred to as pressure receiving areas AIR and APP, respectively) of the input rod 6 and primary piston 2b in the primary liquid chamber 2d. Is done.

The hydraulic pressure adjustment of the master cylinder pressure Pmc is performed with a pressure equilibrium relationship represented by the following equation (1).
Pmc = (FIR + K × Δx) / AIR = (FPP−K × Δx) / APP (1)
Here, each element in the pressure balance equation (1) is as follows.
Pmc: Fluid pressure in the primary fluid chamber 2d (master cylinder pressure)
FIR: Thrust of input rod 6
FPP: Thrust of primary piston 2b
AIR: Pressure receiving area of input rod 6
APP: Pressure receiving area of primary piston 2b
K: Spring constant Δx of the springs 6d and 6e: Relative displacement amount between the input rod 6 and the primary piston 2b In the first embodiment, the pressure receiving area AIR of the input rod 6 is smaller than the pressure receiving area APP of the primary piston 2b. Has been.

  Here, the relative displacement amount Δx is defined as Δx = Xb−Xi where the displacement of the input rod 6 (input rod stroke) is Xi and the displacement of the primary piston 2b (piston stroke) is Xb. Therefore, Δx is 0 at the neutral position of relative movement, has a positive sign in the direction in which the primary piston 2b moves forward (displaces toward the positive direction of the x-axis) with respect to the input rod 6, and has a negative sign in the opposite direction. In the pressure equilibrium type (1), the sliding resistance of the seal is ignored. The thrust FPP of the primary piston 2b can be estimated from the current value of the drive motor 50.

On the other hand, the boost ratio α is expressed by the following equation (2).
α = PM / C × (APP + AIR) / FIR (2)
Therefore, when PM / C of the above equation (1) is substituted into this equation (2), the boost ratio α becomes the following equation (3).
α = (1 + K × Δx / FIR) × (AIR + APP) / AIR (3)

  In the boost control, the drive motor 50 (piston stroke Xb) is controlled so that a target master cylinder pressure characteristic is obtained. Here, the master cylinder pressure characteristic refers to a characteristic of a change in the master cylinder pressure Pmc with respect to the input rod stroke Xi. Corresponding to the stroke characteristic indicating the piston stroke Xb relative to the input rod stroke Xi and the target master cylinder pressure characteristic, a target displacement amount calculation characteristic indicating a change in the relative displacement amount Δx relative to the input rod stroke Xi is obtained. Based on the target displacement amount calculation characteristic data obtained by the verification, a target value of the relative displacement amount Δx (hereinafter, target displacement amount Δx *) is calculated.

  That is, the target displacement amount calculation characteristic indicates a change characteristic of the target displacement amount Δx * with respect to the input rod stroke Xi, and one target displacement amount Δx * is determined corresponding to the input rod stroke Xi. When the rotation of the drive motor 50 (piston stroke Xb) is controlled so as to realize the target displacement amount Δx * determined corresponding to the detected input rod stroke Xi, a master having a magnitude corresponding to the target displacement amount Δx *. Cylinder pressure Pmc is generated in the master cylinder 2.

  Here, as described above, the input rod stroke Xi is detected by the brake operation amount detection device 7, the piston stroke Xb is calculated based on the signal of the rotation angle detection sensor 50a, and the relative displacement amount Δx is detected (calculated). It is obtained from the difference in displacement. Specifically, in the boost control, the target displacement amount Δx * is set based on the detected input rod stroke Xi and the target displacement amount calculation characteristic, and the detected (calculated) relative displacement amount Δx is the target displacement. The drive motor 50 is controlled (feedback control) so as to coincide with the amount Δx *. A stroke sensor that detects the piston stroke Xb may be provided separately.

  When boost control is performed without using a pedal force sensor in this way, the cost can be reduced accordingly. Further, by controlling the drive motor 50 so that the relative displacement amount Δx becomes an arbitrary predetermined value, a larger boost ratio or a smaller boost ratio than the boost ratio determined by the pressure receiving area ratio (AIR + APP) / AIR is obtained. And a braking force based on a desired boost ratio can be obtained.

  The constant boost control is such that the input rod 6 and the primary piston 2b are integrally displaced, that is, the primary motor 2b is always in the neutral position with respect to the input rod 6 and is displaced with a relative displacement amount Δx = 0. 50 is controlled. Thus, when the primary piston 2b is displaced so that Δx = 0, the boost ratio α is uniquely determined as α = (AIR + APP) / AIR according to the above equation (3). Therefore, AIR and APP are set based on the required boost ratio, and the primary piston 2b is controlled so that the displacement amount Xb becomes equal to the input rod stroke Xi. Can be obtained.

  The target master cylinder pressure characteristic in the constant boost control is that the master cylinder pressure Pmc generated as the input rod 6 moves forward (displacement in the positive direction of the x-axis) is a quadratic curve, a cubic curve, or more It becomes large in the form of a multi-order curve (hereinafter collectively referred to as a multi-order curve) in which higher-order curves are combined. The constant boost control has a stroke characteristic in which the primary piston 2b is displaced by the same amount as the input rod stroke Xi (Xb = Xi). In the target displacement amount calculation characteristic obtained based on this stroke characteristic and the target master cylinder pressure characteristic, the target displacement amount Δx * is 0 for every input rod stroke Xi.

  On the other hand, in variable boost control, the target displacement amount Δx * is set to a positive predetermined value, and the drive motor 50 is controlled so that the relative displacement amount Δx becomes this predetermined value. Thus, as the input rod 6 moves forward in the direction of increasing the master cylinder pressure Pmc, the piston stroke Xb becomes larger than the input rod 6 stroke Xi. From the above equation (3), the boost ratio α is (1 + K × Δx / FIR) times as large. That is, this is equivalent to displacing the primary piston 2b by an amount obtained by multiplying the input rod stroke Xi by a proportional gain (1 + K × Δx / FIR). In this way, the boost ratio α becomes variable according to Δx, and the master cylinder pressure control mechanism 5 works as a boost source, and it is possible to greatly reduce the pedal effort while generating a braking force as required by the driver. .

  That is, from the viewpoint of controllability, it is desirable that the proportional gain (1 + K × Δx / FIR) is 1. However, for example, when a braking force exceeding the driver's brake operation amount is required due to an emergency brake or the like, it is temporarily In addition, the proportional gain can be changed to a value exceeding 1. As a result, even with the same amount of brake operation, the master cylinder pressure Pmc can be increased compared to the normal time (when the proportional gain is 1), so that a larger braking force can be generated. Here, the emergency brake can be determined, for example, based on whether or not the time change rate of the signal of the brake operation amount detection device 7 exceeds a predetermined value.

  Thus, in the variable boost control, the primary piston 2b is further advanced relative to the input rod 6, and the relative displacement amount Δx of the primary piston 2b with respect to the input rod 6 increases as the input rod 6 advances. In response to this, the drive motor 50 is controlled such that the increase in the master cylinder pressure Pmc accompanying the forward movement of the input rod 6 is greater than the constant boost control.

  The target master cylinder pressure characteristic in the variable boost control is such that the increase in the master cylinder pressure Pmc generated as the input rod 6 moves forward (displacement in the x-axis positive direction) is larger than that in the constant boost control (multiple curve) The master cylinder pressure characteristics that increase in a steep manner become steeper). Further, the variable boost control has a stroke characteristic in which an increase in the piston stroke Xb with respect to an increase in the input rod stroke Xi is larger than 1. In the target displacement calculation characteristic obtained based on this stroke characteristic and the target master cylinder pressure characteristic, the target displacement Δx * increases at a predetermined rate as the input rod stroke Xi increases.

  Further, as the variable boost control, the drive motor 50 is controlled such that the piston stroke Xb becomes larger than the input rod stroke Xi as the input rod 6 moves in the above-described control, that is, the direction in which the master cylinder pressure Pmc is increased. In addition to this, as the input rod 6 moves in the direction of increasing the master cylinder pressure Pmc, it may include controlling the drive motor 50 so that the piston stroke Xb becomes smaller than the input rod stroke Xi. . Thus, by changing the proportional gain to a value lower than 1, it is possible to apply to regenerative cooperative brake control in which the hydraulic brake is depressurized by the regenerative braking force of the hybrid vehicle.

[Adjustment of booster valve closing amount]
FIG. 2 is a control block diagram of the master cylinder pressure control device 8 according to the first embodiment. The master cylinder pressure control device 8 includes an assist stroke calculation unit 8a, a stroke speed calculation unit (movement speed detection means) 8b, and a closed state. And a valve amount calculation unit (channel resistance control means) 8c.

  The assist stroke calculation unit 8a calculates an assist stroke Xbbase that is a target value of the piston stroke Xb so as to obtain a target displacement amount Δx * for obtaining a desired target stroke characteristic and a target master cylinder pressure characteristic with respect to the input rod stroke Xi. And output to the master cylinder pressure control mechanism 8. A setting map of the assist stroke Xbbase corresponding to the input rod stroke Xi is shown in the block of the assist stroke calculation unit 8a in FIG.

  In this setting map, the characteristics of the assist stroke Xbbase with respect to the input rod stroke Xi when the target displacement amount Δx * is set to 0 are described. However, the brake assist control or the regenerative cooperative brake control increases the braking force as time elapses. Since the target displacement amount Δx * is a value other than 0 during the execution of the above, the map characteristics change accordingly.

  The stroke speed calculation unit 8b calculates the stroke speed ΔXi from the difference between the input rod stroke Xi and the previous value Xi_Z, and outputs it to the valve closing amount calculation unit 8c. The input rod stroke Xi that has been input is held as the previous value Xi_Z until the next calculation cycle.

  The valve closing amount calculation unit 8c calculates the valve closing amount Vpo of the pressure increasing valve (flow path resistance adjusting means) 12, 13, 22, 23 of the wheel cylinder pressure control mechanism 3 based on the stroke speed ΔXi, and the wheel cylinder pressure. Output to the control device 9. A setting map of the valve closing amount Vpo corresponding to the stroke speed Xi is shown in the block of the valve closing amount calculating unit 8c in FIG. In this setting map, the valve closing amount Vpo is changed from 0% (valve opening amount 100%) to 50% (valve opening amount 50%) according to the stroke speed ΔXi, and the valve closing amount Vpo increases as the stroke speed ΔXi increases. Increased characteristics.

The master cylinder pressure control mechanism 8 outputs a control command to the electric motor 50 so that the assist stroke Xbbase calculated by the assist stroke calculation unit 8a is obtained.
The wheel cylinder pressure control device 9 outputs a control command for obtaining the valve closing amount Vpo calculated by the valve closing amount calculating unit 8c to the solenoids of the pressure increasing valves 12, 13, 22, and 23.

[Valve closing amount adjustment processing]
FIG. 3 is a flowchart showing the flow of the valve closing amount adjustment process performed by the master cylinder pressure control device 8 according to the first embodiment. Each step will be described below. This process is repeatedly executed at a predetermined calculation cycle during the driver's braking operation, but is canceled when ABS control or vehicle behavior stabilization control is intervened.

In step S1, the assist rod calculation unit 8a and the stroke speed calculation unit 8b read the input rod stroke Xi, and the process proceeds to step S2.
In step S2, the stroke speed calculation unit 8b calculates the stroke speed ΔXi from the difference between the input rod stroke Xi and the previous value Xi_Z, and the process proceeds to step S3.

In step S3, the assist stroke calculation unit 8a calculates an assist stroke Xbbase corresponding to the input rod stroke Xi, and the process proceeds to step S4.
In step S4, the valve closing amount calculation unit 8c calculates the valve closing amount Vpo corresponding to the stroke speed ΔXi, and the process proceeds to step S5.

In step S5, the assist stroke calculation unit 8a outputs a command for setting the piston stroke Xb to the assist stroke Xbbase to the master cylinder pressure control mechanism 5, and the process proceeds to step S6.
In step S6, the valve closing amount calculation unit 8c outputs a command to the wheel cylinder pressure control device 9 to close the valve openings of the pressure increasing valves 12, 13, 22, and 23 according to the valve closing amount Vpo. Migrate to
In step S7, the input speed of the input rod stroke Xi is stored as the previous value Xi_Z in the stroke speed calculation unit 8b, and the process proceeds to return.

Next, the operation of the first embodiment will be described.
In the brake device 1 according to the first embodiment, the master cylinder pressure Pmc is generated by the input rod 6 that is stroked by the driver's brake pedal operation and the primary piston 2b that is stroked by the drive motor 50 of the master cylinder pressure control mechanism 5. Yes. Here, since there is a response delay in the drive motor 50, as shown in FIG. 4A, when the driver depresses the brake pedal BP to change the input rod stroke Xi, the primary piston 2b strokes with a delay. .

  For this reason, after the driver depresses the brake pedal BP, the brake pedal BP is held, and the time from when the input rod stroke Xi stops until the stroke of the primary piston 2b stops (section AB in FIG. 4). Further, when the master cylinder pressure Pmc increases (FIG. 4B), the input rod input Fi also increases (FIG. 4C). Therefore, although the driver holds the brake pedal BP, the brake pedal reaction force increases, which makes the driver feel uncomfortable.

  In contrast, in the first embodiment, as shown in FIG. 5 (a), the higher the stroke speed ΔXi of the input rod 6, the smaller the valve opening amounts of the pressure increasing valves 12, 13, 22, 23 (the valve closing amount is reduced). Increase the flow path resistance of the brake circuits 10l, 10m, 20l, and 20m connecting the master cylinder 2 and the wheel cylinders 4a to 4d.

  Therefore, when the driver depresses the brake pedal BP, the master cylinder pressure Pmc rises transiently according to the pedal operation speed, so the master cylinder pressure Pmc rises faster than when this control is not applied. (FIG. 5 (b)). For this reason, as shown in FIG.5 (c), the rising delay of the input rod input Fi (brake pedal reaction force) with respect to a pedal stroke can be suppressed, and the discomfort given to a driver can be reduced.

Next, the effect will be described.
The vehicle braking control apparatus according to the first embodiment has the following effects.
(1) The higher the stroke speed ΔXi detected by the stroke speed calculation unit 8b, the larger the valve closing amount Vpo of the pressure increasing valves 12, 13, 22, 23, and the flow path resistance of the brake circuits 10l, 10m, 20l, 20m. The valve closing amount calculation unit 8c is provided. Thereby, the shift | offset | difference of the motion of the brake pedal reaction force with respect to the motion of a brake pedal can be suppressed, and the discomfort given to a driver can be reduced.

  (2) The flow path adjusting means is constituted by the pressure increasing valves 12, 13, 22, and 23 for ABS control for controlling each wheel cylinder pressure. That is, by using a generally popular ABS unit, the cost can be reduced as compared with the case where a flow path adjusting means is newly added. Further, since the pressure increasing valves 12, 13, 22, and 23 are provided for each of the wheel cylinders 4a to 4d, even if the brake circuit adopts an X piping structure, for example, the front wheel side wheel cylinders 4a and 4d are closed. A wheel cylinder for adjusting the valve closing amount Vpo can be arbitrarily set, such as adjusting only the amount Vpo and adjusting only the valve closing amount Vpo of the rear wheel side wheel cylinders 4b and 4c.

FIG. 6 is a control block diagram of the master cylinder pressure control device 8 according to the second embodiment. In addition, about the site | part which is common in Example 1, it represents with the same name and the same code | symbol.
The stop determination unit (stop determination unit) 8d performs vehicle stop determination based on the wheel speed, the accelerator opening, and the shift position of the transmission, and outputs the determination result to the valve closing amount calculation unit 8c.

  When the stop determination unit 8d determines that the vehicle is stopped, the valve closing amount calculation unit 8c determines the valve closing amounts of the pressure increasing valves (flow path resistance adjusting means) 12, 13, 22, 23 based on the stroke speed ΔXi. Vpo1 is calculated and output to the wheel cylinder pressure control device 9. On the other hand, when the vehicle stop determination is made in the stop determination unit 8d, the valve closing amount Vpo1 is set to zero.

  The stop-maintainable master cylinder pressure calculation unit (road surface gradient detection means, stop-maintainable braking force calculation means) 8e detects the road surface gradient based on the longitudinal G acting on the vehicle, and can maintain the vehicle stop at the detected road surface gradient. The master cylinder pressure (master cylinder pressure capable of maintaining stoppage) Pmcs corresponding to the master cylinder pressure (braking force capable of maintaining stoppage) corresponding to the correct braking force (braking force capable of maintaining vehicle stoppage) is output to the stop maintenance correction gain calculating unit 8f. .

  The stop maintenance correction gain calculator 8f calculates a stop maintenance correction gain Kbs (0% ≦ Kbs ≦ 100%) corresponding to the difference between the master cylinder pressure Pmc and the master cylinder pressure Pmcs that can be maintained, and outputs it to the multiplier 8g. To do. A setting map of the stop maintenance correction gain Kbs according to the difference between the master cylinder pressure Pmc and the stop-maintainable master cylinder pressure Pmcs is shown in the block of the stop maintenance correction gain calculation unit 8f in FIG. In this setting map, the stop maintenance correction gain Kbs is zero when Pmc-Pmcs is negative, and increases when Pmc-Pmcs is positive when Pmc-Pmcs is positive, and Pmc-Pmcs is 100% above a predetermined value. It is said.

The multiplier 8g outputs a value obtained by multiplying the valve closing amount Vpo1 and the stop maintaining correction gain Kbs to the wheel cylinder pressure control device 9 as a final valve closing amount Vpo.
In the second embodiment, the valve closing amount calculation unit 8c, the stop maintenance correction gain calculation unit 8f, and the multiplier 8g constitute a flow path resistance control unit.

[Valve closing amount adjustment processing]
FIG. 7 is a flowchart illustrating the flow of the valve closing amount adjustment process executed by the master cylinder pressure control device 8 according to the second embodiment. In addition, about the process which is common in Example 1, the same step number is attached | subjected and description is abbreviate | omitted.

In step S11, the stop maintenance correction gain calculator 8f reads the master cylinder pressure Pmc, and the process proceeds to step S12.
In step S12, the stop determination unit 8d executes a stop determination process, and the process proceeds to step S13. The stop determination process will be described later.

In step S13, the stop-maintainable master cylinder pressure calculation unit 8e executes a stop-maintainable master cylinder pressure calculation process, and proceeds to step S3. The stop-maintainable master cylinder pressure calculation process will be described later.
In step S14, the valve closing amount calculation unit 8c determines whether or not the vehicle stop determination is made by the stop determination unit 8d. If YES, the process proceeds to step S4. If NO, the process proceeds to step S15.

In step S15, since the valve closing amount Vpo1 calculated by the valve closing amount calculating unit 8c becomes zero, the adder 8g outputs the valve closing amount Vpo = 0, and the process proceeds to step S6.
In step S16, the stop maintenance correction gain calculation unit 8f calculates the stop maintenance correction gain Kbs according to the difference between the master cylinder pressure Pmc and the master cylinder pressure Pmcs that can be maintained, and the process proceeds to step S17.
In step S17, the multiplier 8g multiplies the valve closing amount Vpo1 by the stop maintaining correction gain Kbs to calculate the valve closing amount Vpo, and the process proceeds to step S6.

[Stop determination process]
FIG. 8 is a flowchart showing the flow of the vehicle stop determination process in S12, and each step will be described below.
In step S201, the wheel speeds of the four wheels are read, and the process proceeds to step S202.
In step S202, the accelerator opening Apo is read, and the process proceeds to step S203.
In step S203, the shift position of the transmission is read, and the process proceeds to step S204.

In step S204, it is determined whether or not each wheel speed is zero. If YES, the process moves to step S207, and if NO, the process moves to step S205.
In step S205, the stop determination counter is cleared (= 0), and the process proceeds to step S206.

In step S206, vehicle travel determination is performed, and this control is terminated.
In step S207, it is determined whether or not the shift position is in the P range. If YES, the process moves to step S211. If NO, the process moves to step S208.
In step S208, it is determined whether or not the accelerator opening Apo is zero. If YES, the process moves to step S209, and if NO, the process moves to step S205.

In step S209, it is determined whether or not the count value of the stop determination counter is greater than a predetermined value. If YES, the process proceeds to step S211. If NO, the process proceeds to step S210. Here, the predetermined value is a value corresponding to several seconds (for example, 5 seconds).
In step S210, the counter value of the stop determination counter is incremented (+1), and the process proceeds to step S206.
In step S211, a vehicle stop determination is made, and this control is terminated.

  As described above, in the vehicle stop determination process of the first embodiment, when each wheel speed is all zero and the shift is in the P range, or each wheel speed is all zero and the accelerator opening Apo is zero. When the state continues for a predetermined time, the vehicle stop determination is performed, and otherwise, the vehicle travel determination is performed.

[Master cylinder pressure calculation process that can be stopped]
FIG. 9 is a flowchart showing the flow of the stop-maintainable master cylinder pressure calculation process in step S13, and each step will be described below.
In step S301, the wheel speeds of the four wheels are read, and the process proceeds to step S302.

In step S302, the front and rear G sensor values GL are read, and the process proceeds to step S303.
In step S303, a vehicle speed differential deceleration Gw is calculated from the amount of change in tire rotation, and the process proceeds to step S304. The wheel differential deceleration Gw is a value obtained by removing the noise by filtering the difference between the average wheel speed of the four wheels and the previous value (average wheel speed of the four wheels before a predetermined time).

In step S304, the absolute value of the deviation between the vehicle speed differential deceleration Gw and the longitudinal G sensor value GL is calculated as the deceleration difference Ga, and the process proceeds to step S305.
In step S305, the deceleration difference Ga is multiplied by the conversion constant α to calculate the stop-maintainable master cylinder pressure Pmcs, and this control is terminated. Here, the conversion constant α is for converting the deceleration into the master cylinder pressure, and is obtained from vehicle specifications (vehicle weight, brake caliper area, brake pad friction coefficient, disk rotor effective diameter, tire radius, etc.).

Next, the operation of the second embodiment will be described.
In the second embodiment, when the vehicle stop determination is made, the valve closing amount Vpo of the pressure increasing valves 12, 13, 22, 23 is increased as the stroke speed ΔXi is higher (step S1 → step S2 → step S11 → step S12 → Step S13 → Step S3 → Step S5 → Step S14 → Step S4 → Step S16 → Step S17 → Step S6 → Step S7). On the other hand, when the vehicle running determination is made, the valve closing amount Vpo is set to zero (step S1 → step S2 → step S11 → step S12 → step S13 → step S3 → step S5 → step S14 → step S15 → step S6 → Step S7).

  While the vehicle travels, the valve closing amount Vpo of the pressure increasing valves 12, 13, 22, 23 is increased, so that the deceleration is delayed while the vehicle travels. In the second embodiment, the valve closing amount Vpo is increased. Only when the vehicle is stopped. In addition, while traveling, in addition to the relationship between pedal stroke and pedal effort, deceleration is accompanied, even if the brake pedal reaction force rises late with respect to pedal operation, it is difficult to give the driver a feeling of strangeness in the pedal feel, There will be no hindrance.

  In the second embodiment, when the difference between the master cylinder pressure Pmc and the master cylinder pressure Pmcs that can be stopped is zero or more, the valve closing amount Vpo is set to zero. When the driver depresses the brake pedal BP and stops the vehicle in an uphill or downhill scene, if the valve closing amount Vpo of the pressure increasing valves 12, 13, 22, 23 is increased, the vehicle slips down. There is a risk (see “N / A” in FIG. 10).

  On the other hand, in the second embodiment, when the braking force of the vehicle is equal to or less than the braking force capable of maintaining the stop, the valve closing amount Vpo of the pressure increasing valves 12, 13, 22, 23 is set to zero, so that FIG. As shown in (), compared to the case where this control is not applied, the rising delay of the wheel cylinder pressure Pwc can be suppressed. In other words, the braking force required by the driver can be maintained, so that the vehicle can be prevented from sliding down on the slope.

Next, the effect will be described.
The vehicular braking control apparatus according to the second embodiment has the following effects in addition to the effects (1) and (2) of the first embodiment.
(3) A stop determination unit 8d for determining stop is provided, and the flow path resistance control means (the valve closing amount calculation unit 8c, the stop maintenance correction gain calculation unit 8f, and the multiplier 8g) is closed when it is determined that the vehicle is stopped. Since the valve amount Vpo is increased, it is possible to prevent a delay in the generated deceleration with respect to the driver's required deceleration during traveling.

  (4) A stop resistance control unit 8e that calculates a stop sustainable braking force for a vehicle on a road gradient, and master cylinder pressure sensors 3a and 3b that detect a master cylinder pressure Pmc, and a flow path resistance control unit. Increases the valve closing amount Vpo when the master cylinder pressure Pmc is equal to or greater than the braking force Pmcs capable of maintaining stoppage. As a result, it is possible to achieve both maintenance of the stopped state and reduction in the uncomfortable feeling of the pedal feel.

FIG. 11 is a control block diagram of the master cylinder pressure control device 8 according to the third embodiment. In addition, about the site | part which is common in Example 1 or Example 2, it represents with the same name and the same code | symbol.
The temperature correction gain calculator 8i calculates a temperature correction gain Ktb (0% ≦ Ktb ≦ 100%) based on the brake fluid temperature Tb detected by the brake fluid temperature sensor (temperature detection means) 8h arranged in the master cylinder 2. Calculate and output to multiplier 8g. A setting map of the temperature correction gain Ktb corresponding to the brake fluid temperature Tb is shown in the block of the temperature correction gain calculation unit 8i in FIG.

  In this setting map, the temperature correction gain Ktb has a characteristic such that it becomes 100% when the brake fluid temperature Tb is equal to or higher than zero degrees Celsius, and becomes smaller as the brake fluid temperature Tb is lower when the brake fluid temperature Tb is negative. Further, the temperature correction gain Ktb is set to 0% at a temperature of −20 ° C. or less where the viscosity of the brake fluid rapidly increases.

The multiplier 8g outputs a value obtained by multiplying the valve closing amount Vpo1, the stop maintaining correction gain Kbs, and the temperature correction gain Ktb to the wheel cylinder pressure control device 9 as the final valve closing amount Vpo.
In the third embodiment, the valve closing amount calculation unit 8c, the stop maintenance correction gain calculation unit 8f, the multiplier 8g, and the temperature correction gain calculation unit 8i constitute a flow path resistance control unit.

[Valve closing amount adjustment processing]
FIG. 12 is a flowchart illustrating the flow of the valve closing amount adjustment process executed by the master cylinder pressure control device 8 according to the third embodiment. In addition, about the process which is common in Example 1 or Example 2, the same step number is attached | subjected and description is abbreviate | omitted.

In step S21, the temperature correction gain calculator 8i reads the brake fluid temperature Tb, and proceeds to step S12.
In step S22, the temperature correction gain calculation unit 8i calculates a temperature correction gain Ktb corresponding to the brake fluid temperature Tb, and the process proceeds to step S23.
In step S23, the multiplier 8g multiplies the valve closing amount Vpo1, the stop maintaining correction gain Kbs, and the temperature correction gain Ktb to calculate the valve closing amount Vpo, and the process proceeds to step S6.

Next, the operation of the third embodiment will be described.
In the third embodiment, the lower the brake fluid temperature Tb, the smaller the valve closing amount Vpo, thereby suppressing the flow path resistance increase amount. Since the brake fluid has a characteristic that the viscosity increases as the temperature decreases, if the flow path resistance is increased, the introduction of the brake fluid from the master cylinder 2 to each of the wheel cylinders 4a to 4d is inhibited, and the master cylinder pressure Pmc is excessively increased. Get higher.

  Therefore, in the third embodiment, the valve closing amount Vpo is reduced as the brake fluid temperature Tb is lower, so that an excessive increase in the brake pedal reaction force and the wheel cylinder in an extremely low temperature environment, that is, when the viscosity of the brake fluid is high. The generation delay of the pressure Pwc can be prevented.

Next, the effect will be described.
In addition to the effects (1) and (2) of the first embodiment and the effects (3) and (4) of the second embodiment, the vehicle brake control device of the third embodiment has the following effects.
(5) The flow resistance control means (the valve closing amount calculation unit 8c, the stop maintenance correction gain calculation unit 8f, the multiplier 8g, and the temperature correction gain calculation unit 8i) has a low brake fluid temperature Tb detected by the temperature sensor 8h. Thus, in order to suppress the flow path resistance increase amount, it is possible to prevent an excessive increase in the brake pedal reaction force and a delay in generation of the wheel cylinder pressure when the viscosity of the brake fluid is high.

FIG. 13 is a control block diagram of the master cylinder pressure control device 8 according to the third embodiment. In addition, about the site | part which is common in Example 1 or Example 2, it represents with the same name and the same code | symbol.
The reaction force target calculation unit (target reaction force calculation means) 8j calculates a reaction force target Ficom based on the input rod stroke Xi and outputs it to the comparator 8m. A reaction force target Ficom setting map corresponding to the input rod stroke Xi is shown in the reaction force target calculation unit 8j in FIG. In this setting map, the reaction force target Ficom increases as the input rod stroke Xi increases.

Based on the input rod stroke Xi, the master cylinder pressure Pmc, and the piston stroke Xb, the estimated reaction force calculation unit (reaction force estimation means) 8k calculates the following equation (4) from the pressure equilibrium relationship shown in equation (1). The estimated reaction force Fir, which is an estimated value of the brake pedal reaction force, is calculated with reference.
From equation (1)
Pmc × AIR = (FIR + K × Δx)… (1) '
Here, since Δx = Xb−Xi, if FIR = Fir,
Fir = Pmc × AIR + K × (Xi−Xb)… (4)

The comparator 8m outputs the difference between the reaction force target Ficom and the estimated reaction force Fir to the reaction force deviation correction gain calculation unit 8n.
The reaction force deviation correction gain calculation unit 8n calculates a reaction force deviation correction gain Kbf (0% ≦ Kbf ≦ 100%) according to the difference between the reaction force target Ficom and the estimated reaction force Fir, and outputs it to the multiplier 8g. . A reaction force deviation correction gain Kbf setting map corresponding to the difference between the reaction force target Ficom and the estimated reaction force Fir is shown in the reaction force deviation correction gain calculation unit 8n of FIG. In this setting map, the reaction force deviation correction gain Kbf is zero when Ficom-Fir is negative, and increases when Ficom-Fir is large when Ficom-Fir is negative. It is characteristic.

The multiplier 8g outputs a value obtained by multiplying the valve closing amount Vpo1, the stop maintaining correction gain Kbs, and the reaction force deviation correction gain Kbf to the wheel cylinder pressure control device 9 as the final valve closing amount Vpo.
In the fourth embodiment, the valve closing amount calculation unit 8c, the stop maintenance correction gain calculation unit 8f, the multiplier 8g, and the reaction force deviation correction gain calculation unit 8n constitute flow path resistance control means.
In the first to third embodiments, the pressure increasing valves 12, 13, 22, 23 are used as the flow path resistance adjusting means. However, in the fourth embodiment, the out side gate valves 11, 21 of the wheel cylinder pressure control mechanism 3 are flown. Used as a road resistance adjusting means.

[Valve closing amount adjustment processing]
FIG. 14 is a flowchart showing the flow of the valve closing amount adjustment process executed by the master cylinder pressure control device 8 of the fourth embodiment, and each step will be described below. In addition, about the process which is common in Example 1 or Example 2, the same step number is attached | subjected and description is abbreviate | omitted.

In step S31, the estimated reaction force calculator 8k reads the piston stroke Xb, and proceeds to step S12.
In step S32, the reaction force target calculation unit 8j calculates a reaction force target Ficom based on the input rod stroke Xi, and proceeds to step S33.
In step S33, the estimated reaction force calculator 8k calculates the estimated reaction force Fir with reference to the equation (4) from the input rod stroke Xi, the master cylinder pressure Pmc, and the piston stroke Xb, and the process proceeds to step S34.

In step S34, the reaction force deviation correction gain calculation unit 8n calculates a reaction force deviation correction gain Kbf according to the difference between the reaction force target Ficom and the estimated reaction force Fir, and proceeds to step S16.
In step S35, the multiplier 8g multiplies the valve closing amount Vpo1, the stop maintaining correction gain Kbs, and the reaction force deviation correction gain Kbf to calculate the valve closing amount Vpo, and the process proceeds to step S6.

Next, the operation of the fourth embodiment will be described.
In the fourth embodiment, the brake pedal reaction force characteristic is obtained by correcting the valve closing amount Vpo according to the reaction force deviation correction gain Kbf according to the difference between the reaction force target Ficom and the estimated reaction force Fir in the assist stroke Xbbase. Approach the target reaction force characteristics set in advance.

  When the control of this embodiment is not applied, when the driver slowly depresses the brake pedal BP, the input rod input Fi becomes larger than the reaction force target Ficom as shown in FIG. Is done. Therefore, in Example 4, when the driver slowly depresses the brake pedal BP by correcting the valve closing amount Vpo so as to eliminate the difference between the reaction force target Ficom and the estimated reaction force Fir, the brake pedal reaction force is reduced. It can suppress becoming excess.

Next, the effect will be described.
The vehicle brake control device according to the fourth embodiment has the following effects in addition to the effects (1) and (2) of the first embodiment and the effects (3) and (4) of the second embodiment.
(6) The flow path resistance control means (the valve closing amount calculation unit 8c, the stop maintenance correction gain calculation unit 8f, the multiplier 8g, and the reaction force deviation correction gain calculation unit 8n) is a target in which the reaction force of the brake pedal BP is set in advance. The valve closing amount Vpo is adjusted so as to approach the reaction force characteristic. Thereby, it can suppress that a brake pedal reaction force becomes excess.

  (7) Since the flow path resistance adjusting means is constituted by the normally open out-side gate valves 11 and 21 for opening and closing the brake circuits 10k and 20k, the pressure increasing valves 12, 13, 22, and 23 are used as the flow path resistance adjusting means. Compared to the case, the number of solenoids to be controlled can be halved and power consumption can be suppressed.

(Other examples)
The vehicular braking control apparatus of the present invention has been described based on the embodiments. However, the specific configuration is not limited to these embodiments, and the invention according to each claim of the claims is described. Design changes and additions are allowed without departing from the gist.

For example, in the first embodiment, the example in which the pressure increasing valve or the out-side gate valve of the wheel cylinder pressure control mechanism capable of executing the ABS control, the vehicle behavior stabilization control, or the like is used as the flow path resistance adjusting means. The resistance adjusting means only needs to be able to adjust the flow path resistance of the brake circuit connecting the master cylinder and each wheel cylinder. For example, a variable orifice may be used.
The correction of the valve closing amount by the third embodiment and the temperature correction gain may be combined with the correction of the valve closing amount by the reaction force deviation correction gain of the second embodiment.

BP Brake pedal 2b Primary piston (assist member)
3a, 3b Master cylinder pressure sensor (master cylinder pressure detection means)
5 Master cylinder pressure control mechanism (brake booster)
6 Input rod (input member)
6d, 6e Spring (biasing means)
7 Brake operation amount detection device (movement amount detection means)
8b Stroke speed calculation unit (moving speed detection means)
8c Valve closing amount calculation unit (channel resistance control means)
8d Stop determination unit (stop determination means)
8e Master cylinder pressure calculating unit capable of maintaining stop (road surface gradient detecting means, braking force calculating means capable of maintaining stop)
8f Stop maintenance correction gain calculation unit (channel resistance control means)
8g multiplier (channel resistance control means)
8h Brake fluid temperature sensor (temperature detection means)
8i Temperature correction gain calculator (channel resistance control means)
8j reaction force target calculation unit (target reaction force calculation means)
8k estimated reaction force calculation unit (reaction force estimation means)
8n reaction force deviation correction gain calculation unit (channel resistance control means)
11, 21 Out side gate valve (channel resistance adjustment means)
12, 13, 22, 23 Booster regulator (flow path resistance adjusting means)
50 Drive motor (boost actuator)

Claims (6)

An input member that moves forward and backward by the operation of the brake pedal, an assist member that is movable relative to the direction of movement of the input member, and the input member is directed toward the neutral position of the relative displacement of the assist member. A brake fluid that is boosted in the master cylinder by the assist thrust applied to the assist member in accordance with the movement of the input member. A brake booster for generating pressure,
A brake circuit connecting the master cylinder and each wheel cylinder;
Flow path resistance adjusting means capable of adjusting the flow path resistance of the brake circuit;
A moving speed detecting means for detecting a moving speed of the input member;
Stop determination means for determining vehicle stop;
When the stop determination means determines that the vehicle is stopped, the flow resistance control means increases the flow resistance of the flow resistance adjustment means as the movement speed of the input member detected by the movement speed detection means increases. When,
A vehicular braking control apparatus comprising: The vehicle brake control device according to claim 1,
Road surface gradient detecting means for detecting the road surface gradient;
A stop-sustainable braking force calculating means for calculating a stop-sustainable braking force of the vehicle at the road surface gradient detected by the road surface slope detecting means;
Master cylinder pressure detecting means for detecting the master cylinder pressure;
With
When the braking force according to the master cylinder pressure detected by the master cylinder pressure detecting unit is equal to or greater than the stop-sustainable braking force calculated by the stopable braking force calculating unit, the flow path resistance control unit A vehicular braking control device that performs road resistance increase. In the vehicle brake control device according to claim 1 or 2,
A movement amount detecting means for detecting a movement amount of the input member;
Target reaction force calculation means for calculating a target reaction force based on the movement amount detected by the movement amount detection means;
With
The vehicular brake control device, wherein the flow path resistance control unit controls the flow path resistance so that a reaction force of the brake pedal approaches a preset target reaction force characteristic. The vehicle brake control device according to any one of claims 1 to 3,
Temperature detecting means for detecting the temperature of the brake fluid,
The vehicular braking control device, wherein the flow path resistance control means suppresses the flow path resistance increase as the temperature of the brake fluid detected by the temperature detection means is lower. The vehicle brake control device according to any one of claims 1 to 4,
The vehicular braking control device according to claim 1, wherein the flow path resistance adjusting means is an ABS control pressure increasing valve for controlling each wheel cylinder pressure. The vehicle brake control device according to any one of claims 1 to 4,
The vehicular braking control apparatus, wherein the flow path resistance adjusting means is a normally open out-side gate valve that opens and closes the brake circuit.

Images