JP2009269465A - Control device of braking device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To restrain degradation of operation feeling of a brake pedal at least while a vehicle is at a stop on a slope. <P>SOLUTION: A brake actuator 50 has a first master cutoff valve 52A and a second master cutoff valve 52B. While a vehicle where the brake actuator 50 is mounted is at a stop on a downgrade slope, the first master cutoff valve 52A and the second master cutoff valve 52B are opened for releasing the brake force of the vehicle to lower the brake fluid pressure in pipes between the valves and brake force generating means 41FL, 41FR, 41RL, 41RR. Under this constitution, a speed to lower the brake fluid pressure is decreased as the slope becomes larger. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a braking device that generates braking force on wheels of a vehicle.

  Vehicles such as passenger cars, buses, and trucks are provided with braking devices. In recent years, electronically controlled braking that can adjust the braking force of each wheel by adjusting the brake fluid pressure to the braking force generation means provided on each wheel by the pressurizing means and the brake fluid pressure control unit. Devices are becoming popular. For example, in Patent Document 1, a master cut valve is provided on a brake fluid path from a master cylinder to a wheel cylinder, and the pressure is increased by a pump as a pressurizing unit by adjusting the opening of the master cut valve. A brake device for supplying brake fluid to a wheel cylinder is disclosed.

JP 2004-276666 A (0023-0031, FIG. 1)

  The technique disclosed in Patent Document 1 is such that the sum of the regenerative braking force applied to the driving wheels of the vehicle and the friction braking force applied to the driving wheels and the driven wheels of the vehicle becomes the braking force required for the vehicle. At low speed, regenerative cooperative control can be performed in which the deficiency of the regenerative braking force is compensated by the friction braking force of the pump. When this control is executed, the pump is stopped after the vehicle is stopped. At this time, the brake fluid on the wheel cylinder side moves to the master cylinder side from the master cut valve disposed between the master cylinder and the wheel cylinder, and the brake fluid pressure on the wheel cylinder side may decrease.

  For example, when regenerative cooperative control is executed when the vehicle is stopped on a slope, the braking force is secured, but the pressure change is transmitted to the brake pedal because the pressure of the brake fluid on the wheel cylinder side decreases. There is a risk that the feeling of operation of the brake pedal will be reduced.

  The present invention has been made in view of the above, and an object of the present invention is to provide a control device for a braking device that can suppress a decrease in the operation feeling of a brake pedal at least when a vehicle is on a slope.

  In order to solve the above-described problems and achieve the object, a control device for a braking device according to the present invention includes a braking force generation unit that generates braking force on wheels provided in a vehicle by supplying brake fluid, and a brake pedal. A master cylinder that generates a brake fluid pressure in accordance with a pedaling force; a pump that pressurizes the brake fluid and supplies the brake fluid pressurized from the master cylinder to the brake fluid passage to the braking force generation unit; A control device of a braking device comprising a flow rate control valve provided on the brake fluid passage between the master cylinder and the braking force generating means, wherein the slope of the road surface on which the vehicle is running or stopped The road surface gradient detecting means for detecting the vehicle and the vehicle controlling the flow rate control valve to depressurize the brake fluid pressurized by the pump and stopping on the slope And a flow rate control valve control means for reducing the speed at which the brake fluid is depressurized as the gradient detected by the road surface gradient detection means increases. To do.

  As a preferred aspect of the present invention, in the braking device, the flow control valve control means is configured to reduce a brake fluid pressure at an outlet of the flow control valve and a brake fluid pressure at an inlet when the pump is stopped. It is preferable to increase the differential pressure more than before the pump stops.

  As a desirable aspect of the present invention, in the braking device, the flow rate control valve control means sets the pressure of the brake fluid between the flow rate control valve and the braking force generation means after the pump is stopped. It is preferable to maintain a predetermined value larger than zero.

  In a preferred aspect of the present invention, in the braking device, the flow control valve control means is configured to reduce the amount of brake fluid between the flow control valve and the braking force generation means when the vehicle stops at a slope. It is preferable that the pressure is maintained at a pressure higher than a pressure necessary for the braking force generation means to generate a braking force necessary to stop the vehicle at the slope.

  The present invention can suppress a decrease in operation feeling of the brake pedal when there is a vehicle on at least a slope and when the vehicle is on a slope.

  Hereinafter, the present invention will be described in detail with reference to the drawings. The present invention is not limited by the best mode for carrying out the present invention (hereinafter referred to as an embodiment). In addition, constituent elements in the following embodiments include those that can be easily assumed by those skilled in the art, those that are substantially the same, and those in a so-called equivalent range. In the present invention, the pressure is increased by the pump by adjusting the opening degree of the flow control valve provided in the brake fluid path from the master cylinder to the braking force generating means including the wheel cylinder, the brake pad, the disk rotor, and the like. The present invention can be suitably applied to a braking device that supplies the brake fluid thus applied to the braking force generating means.

  In the present embodiment, the flow rate control valve provided on the brake fluid passage between the master cylinder and the braking force generating means reduces the brake fluid pressurized by the pump, thereby stopping the vehicle on a downward slope. When releasing the braking force, the speed of depressurizing the brake fluid decreases as the gradient increases.

  FIG. 1 is a schematic diagram showing a vehicle on which a braking device according to this embodiment is mounted. Vehicle 100 includes wheels 10FL, 10FR, 10RL, and 10RR. The vehicle 100 also includes a braking device 101 that generates braking force (wheel braking force) on the wheels 10FL, 10FR, 10RL, and 10RR. The braking force that the braking device 101 generates on the wheels 10FL, 10FR, 10RL, and 10RR is a mechanical braking force, and more specifically, a braking force that uses a frictional force.

  The braking device 101 applies mechanical wheel braking torque due to friction to the respective wheels 10FL, 10FR, 10RL, 10RR by the pressure of the brake fluid, and applies wheel braking force to the respective wheels 10FL, 10FR, 10RL, 10RR. By generating, a force for braking the vehicle 100 (vehicle braking force) is generated. Here, FL represents the left front of the vehicle 100, FR represents the right front of the vehicle 100, RL represents the left rear of the vehicle 100, and RR represents the right rear of the vehicle 100 (the same applies hereinafter).

  The vehicle 100 includes a drive device 102. The drive device 102 is configured to include an electric motor 60 that is power generation means and a transmission device 61 that is speed ratio changing means. As described above, the vehicle 100 is an electric vehicle using the electric motor 60 as power generation means, but the vehicle 100 is not limited to this in the present embodiment.

  The electric motor 60 receives power from the battery 4 and generates power. The electric power from the battery 4 is adjusted by a power conversion device 3 controlled by a drive control ECU (Electronic Control Unit) 2 and supplied to the electric motor 60. As a result, the output (rotation speed and torque) of the electric motor 60 is adjusted. The output of the electric motor 60 is transmitted to the left front drive shaft 62FL and the right front drive shaft 62FR via the transmission 61. Thereby, the electric motor 60 drives the wheel 10FL attached to the left front drive shaft 62FL and the wheel 10FR attached to the right front drive shaft 62FR. The drive control ECU 2 controls the electric motor 60 and the transmission 61 in accordance with the driving conditions of the vehicle 100 and causes the vehicle 100 to travel in an appropriate state. Here, the transmission 61 is not necessarily provided.

  In the present embodiment, the braking device 101 includes braking force generating means 41FL, 41FR, 41RL, and 41RR, braking force generating means side brake fluid piping 42FL, 42FR, 42RL, and 42RR that are brake fluid passages, and pedal force increasing means (hereinafter referred to as “braking force increasing means”). A brake cylinder) 43, a master cylinder 44, and a brake fluid pressure adjusting means (hereinafter referred to as “brake actuator”) 50.

  The braking force generating means 41FL, 41FR, 41RL, 41RR are mechanical and frictional braking means, and are composed of wheel cylinders, brake pads, disk rotors, and the like provided on the respective wheels 10FL, 10FR, 10RL, 10RR. The braking force generating means 41FL, 41FR, 41RL, and 41RR are friction braking devices that generate a braking force (friction braking force) using, for example, a frictional force generated between a brake pad and a disk rotor.

  The brake booster 43 increases the pedal effort input to the brake pedal 20 by the driver. Here, the brake pedal 20 includes a pedal arm 20A that transmits the driver's pedaling force to the master cylinder 44 via the brake booster 43, and a pedal body 20P that is attached to the pedal arm 20A and transmits the driver's pedaling force to the pedal arm 20A. It consists of. The pedaling force of the driver is a force for generating a wheel braking force on the wheels 10FL, 10FR, 10RL, 10RR. The master cylinder 44 converts the pedal effort increased by the brake booster 43 into brake fluid pressure (brake fluid pressure). The brake actuator 50 transmits the converted brake fluid pressure to the respective brake force generating means side brake fluid pipes 42FL, 42FR, 42RL, 42RR as it is or after adjustment.

  The brake actuator 50 and the respective braking force generation means 41FL, 41FR, 41RL, 41RR are connected by a braking force generation means side brake fluid piping 42FL, 42FR, 42RL, 42RR. The brake actuator 50 and the master cylinder 44 are connected by a master cylinder side first brake fluid pipe 45A and a master cylinder side second brake fluid pipe 45B.

  Brake fluid passage provided in master cylinder 44, braking force generating means side brake fluid piping 42FL, 42FR, 42RL, 42RR, master cylinder side first brake fluid piping 45A, master cylinder side second brake fluid piping 45B, and brake actuator 50 Is filled with brake fluid. Thus, the pedaling force input from the brake pedal 20 and input to the master cylinder 44 via the brake booster 43 is the master cylinder side first brake fluid piping 45A, the master cylinder side second brake fluid piping 45B and the braking force generating means. It is transmitted to the wheel cylinders constituting the respective braking force generating means 41FL, 41FR, 41RL, 41RR via internal brake fluid such as the side brake fluid pipes 42FL, 42FR, 42RL, 42RR. In this way, the braking device 101 generates braking force on the wheels included in the vehicle 100 via the brake fluid to the braking force generation means that generates braking force on the wheels 10FL, 10FR, 10RL, and 10RR included in the vehicle 100. Transmit power for

  In the present embodiment, the brake actuator 50 has a function of individually adjusting the brake fluid pressures of the respective brake force generation means side brake fluid pipes 42FL, 42FR, 42RL, and 42RR. The brake actuator 50 can generate a wheel braking force having an independent magnitude for each of the wheels 10FL, 10FR, 10RL, and 10RR. A braking device control device 1 (hereinafter referred to as a braking control device) 1 shown in FIG. 1 controls driving of the brake actuator 50, so that so-called ABS control, brake assist control, and the like are performed.

  The operation of the braking device 101 is controlled by the braking control device 1 and generates wheel braking force corresponding to the target vehicle braking force (target vehicle braking force) on the wheels 10FL, 10FR, 10RL, 10RR. For example, the braking control device 1 is configured by combining a microcomputer, a memory, and the like, and controls the wheel braking force with respect to the wheels 10FL, 10FR, 10RL, and 10RR, and realizes the braking control device according to the present embodiment. The brake control device 1 includes a master cylinder pressure sensor 31, a stroke sensor 32, and a pedaling force detection as means for detecting the operation state of the brake, that is, the operation state of the brake pedal 20 by the driver of the vehicle 100 (brake operation detection means). A switch 33 is connected. The braking device 101 includes at least one brake operation detection unit. The stroke sensor 32 is not necessarily provided.

  In addition, an ammeter 34, a resolver 35, a first outlet side brake hydraulic pressure sensor 36A, a second outlet side brake hydraulic pressure sensor 36B, and an inclination angle sensor 37 are connected to the braking control device 1. . The ammeter 34 is an electric motor drive current detection unit that detects a drive current of an electric motor that is a brake fluid pressurization unit drive unit that drives a brake fluid pressurization unit provided in the brake actuator 50. The resolver 35 is an electric motor rotational speed detecting means for detecting the rotational speed (the rotational speed per unit time) of the electric motor. The inclination angle sensor 37 is road surface gradient detection means for detecting information for obtaining the inclination of the road surface on which the vehicle 100 is traveling or stopped. In the present embodiment, as the information, the vehicle 100 is traveling or stopped. The slope of the road surface is detected. The configuration of the brake actuator 50, the brake fluid pressurizing means, the brake fluid pressurizing means driving means, the first outlet side brake fluid pressure sensor 36A, and the second outlet side brake fluid pressure sensor 36B provided in the brake actuator 50 will be described later. .

  The braking control device 1 includes a braking / driving force calculation unit 1a, a road surface gradient calculation unit 1b, a brake hydraulic pressure calculation unit 1c, a control condition determination unit 1d, a brake hydraulic pressure reduction parameter calculation unit 1e, and a braking device control unit. (Flow control valve control means) 1f and a storage unit 1m. In the present embodiment, the tilt angle sensor 37 is included in the braking control device 1. The braking / driving force calculation unit 1a calculates the braking force requested by the driver of the vehicle 100 and the driving force of the vehicle 100. The road surface gradient calculation unit 1 b calculates the gradient of the road surface on which the vehicle 100 travels or stops based on information acquired from the inclination angle sensor 37 connected to the braking control device 1. The brake fluid pressure calculation unit 1c calculates the brake fluid pressure in the braking control according to the present embodiment. The control condition determination unit 1d determines a condition for braking control of the braking device 101. The brake fluid pressure reduction parameter calculation unit 1e calculates control parameters necessary for releasing the brake by reducing the brake fluid pressure in the braking control according to the present embodiment.

  The braking device control unit 1f controls the operation of the brake actuator 50 to execute so-called ABS control, brake assist control, or braking control according to the present embodiment. As described above, the braking device control unit 1f generates the wheel braking force (target wheel braking force) targeted by each of the wheels 10FL, 10FR, 10RL, and 10RR on each of the wheels 10FL, 10FR, 10RL, and 10RR. The storage unit 1m stores a computer program and control data for executing braking control according to the present embodiment, or a computer program and control data for executing ABS control and brake assist control. The braking control device 1 is connected to the drive control ECU 2 and configured to exchange information with each other so that the braking control device 1 and the drive control ECU 2 can perform cooperative control.

  Here, the target vehicle braking force is a target value required for braking the vehicle 100 mainly corresponding to the operation state amount of the brake pedal 20 by the driver. The operation state amount of the brake pedal 20 is a parameter indicating a state when the brake pedal 20 is operated or an input state with respect to the brake pedal 20, for example, a pedal stroke amount, a pedal stroke position, a pedaling force, a pedal operation speed, and the like. . The target wheel braking force is a braking force that is shared by the wheels 10FL, 10FR, 10RL, and 10RR in order to apply the target vehicle braking force to the vehicle 100.

  The braking device control unit 1f obtains the target wheel braking force to be generated in each of the wheels 10FL, 10FR, 10RL, 10RR so that the target vehicle braking force is satisfied. At that time, for example, the acceleration in the longitudinal direction of the vehicle 100 is obtained. It is desirable to consider the lateral acceleration of the vehicle 100, the yaw moment, the slip ratios of the wheels 10FL, 10FR, 10RL, 10RR, and the like. In other words, the target wheel braking force of each of the wheels 10FL, 10FR, 10RL, 10RR is shared with each of the wheels 10FL, 10FR, 10RL, 10RR at least within a range where the behavior of the vehicle 100 does not become unstable. It is preferable to make it.

  FIG. 2 is a device configuration diagram showing a configuration of a brake actuator provided in the braking device according to the present embodiment. The brake actuator 50 includes a first hydraulic pressure transmission system 51A that transmits the brake hydraulic pressure from the master cylinder 44 to the braking force generation means 41FR and 41RL, and a second hydraulic pressure transmission system 51B that transmits the braking force generation means 41FL and 41RR. With. The first hydraulic pressure transmission system 51A is connected to the master cylinder 44 by a master cylinder side first brake fluid piping 45A that is a brake fluid passage, and the second hydraulic pressure transmission system 51B is a master cylinder side second fluid that is a brake fluid passage. The brake fluid pipe 45B is connected to the master cylinder 44.

  In the first hydraulic pressure transmission system 51A, the brake hydraulic pressure from the master cylinder 44 includes the master cylinder side first brake fluid piping 45A, the first master cut valve 52A that is a flow control valve, and the first high pressure brake that is a brake fluid passage. This is transmitted to the braking force generating means 41FR and 41RL via the liquid pipe 58A and the holding solenoid valves 53FR and 53RL. Pressure reducing solenoid valves 54FR and 54RL are provided between the holding solenoid valves 53FR and 53RL and the braking force generation means 41FR and 41RL.

  By operating the holding solenoid valves 53FR, 53RL and the pressure reducing solenoid valves 54FR, 54RL, the brake fluid pressure acting on the braking force generating means 41FR, 41RL is increased or decreased, and the braking forces of the wheels 10FR, 10RL are adjusted. For example, the brake fluid pressure acting on the braking force generating means 41FR and 41RL is increased or decreased by changing the duty ratio between the opening time and the closing time of the holding solenoid valves 53FR and 53RL and the pressure reducing solenoid valves 54FR and 54RL.

  In the second hydraulic pressure transmission system 51B, the brake hydraulic pressure from the master cylinder 44 includes the master cylinder side second brake fluid piping 45B, the second master cut valve 52B which is a flow control valve, and the second high pressure brake which is a brake fluid passage. This is transmitted to the braking force generating means 41FL, 41RR via the liquid pipe 58B and the holding solenoid valves 53FL, 53RR. Pressure reducing solenoid valves 54FL and 54RR are provided between the holding solenoid valves 53FL and 53RR and the braking force generating means 41FL and 41RR.

  By operating the holding solenoid valves 53FL, 53RR and the pressure reducing solenoid valves 54FL, 54RR, the brake fluid pressure acting on the braking force generating means 41FL, 41RR is increased or decreased, and the braking force of the wheels 10FL, 10RR is adjusted. For example, by changing the duty ratio between the opening time and the closing time of the holding solenoid valves 53FL and 53RR and the pressure reducing solenoid valves 54FL and 54RR, the brake fluid pressure acting on the braking force generating means 41FL and 41RR is increased or decreased.

  The first master cut valve 52A and the second master cut valve 52B (hereinafter referred to as the master cut valve 52 as necessary), which are flow rate control valves, have linear solenoids and springs. The master cut valve 52 is a normally open electromagnetic flow control valve that is open when the solenoid is not energized and that can adjust the opening by adjusting the current supplied to the solenoid. The master cut valve 52 changes its opening degree linearly by using a linear solenoid. As a result, the master cut valve 52 adjusts the opening so that the pressure difference between the brake fluid pressure Pe at the outlet and the brake fluid pressure Pi at the inlet (master cut valve differential pressure) ΔP_SMC (= Pe−Pi). And the differential pressure ΔP_SMC can be changed linearly.

  Here, the brake fluid pressure on the outlet side of the first master cut valve 52A and the second master cut valve 52B is the brake fluid pressure inside the first high pressure brake fluid piping 58A and the second high pressure brake fluid piping 58B, respectively. The brake fluid pressure on the inlet side of the first master cut valve 52A and the second master cut valve 52B is the brake fluid pressure inside the master cylinder side first brake fluid piping 45A and the master cylinder side second brake fluid piping 45B, respectively. is there. The master cut valve differential pressure of the first master cut valve 52A is calculated from the brake fluid pressure in the first high pressure brake fluid piping 58A and the brake fluid pressure in the master cylinder side first brake fluid piping 45A. The master cut valve differential pressure of the second master cut valve 52B is calculated from the brake fluid pressure in the second high pressure brake fluid pipe 58B and the brake fluid pressure in the master cylinder side second brake fluid pipe 45B. The master cut valve differential pressure can also be obtained from the control current supplied to the master cut valve 52.

  The pressure on the inlet side of the first master cut valve 52A and the second master cut valve 52B is detected by the master cylinder pressure sensor 31 and acquired by the braking control device 1 shown in FIGS. Also, the brake fluid pressure inside the first high-pressure brake fluid piping 58A and the second high-pressure brake fluid piping 58B is detected by the first outlet-side brake fluid pressure sensor 36A and the second outlet-side brake fluid pressure sensor 36B attached thereto. Then, it is acquired by the braking control device 1 shown in FIGS. The first outlet side brake hydraulic pressure sensor 36A and the second outlet side brake hydraulic pressure sensor 36B are not necessarily provided.

  The first brake fluid reservoir 57A is connected to the outlets of the pressure reducing solenoid valves 54FR and 54RL and the first brake fluid piping 45A on the master cylinder side. The outlets of the pressure reducing solenoid valves 54FL and 54RR and the master cylinder side second brake fluid pipe 45B are connected to the second brake fluid reservoir 57B. The first brake fluid reservoir 57A and the second brake fluid reservoir 57B are brake fluid storage means for storing brake fluid.

  The brake actuator 50 includes a first pump 56A that pressurizes the brake fluid in the first hydraulic pressure transmission system 51A in order to adjust the hydraulic pressure of the first hydraulic pressure transmission system 51A, and the second hydraulic pressure transmission system 51B. In order to adjust the hydraulic pressure, a second pump 56B for pressurizing the brake fluid in the second hydraulic pressure transmission system 51B is provided. When the first pump 56A pressurizes the brake fluid in the first hydraulic pressure transmission system 51A, the pressure of the brake fluid applied to the braking force generating means 41FR and 41RL, that is, the hydraulic pressure increases. Similarly, when the second pump 56B pressurizes the brake fluid in the second hydraulic pressure transmission system 51B, the hydraulic pressure applied to the braking force generation means 41FL and 41RR increases. Thus, the first pump 56A and the second pump 56B function as brake fluid pressurizing means.

  The first pump 56A and the second pump 56B are driven by a pump driving motor 55 which is a brake fluid pressurizing means driving means. The braking control device 1 controls the operation of the pump drive motor 55 based on the drive current of the pump drive motor 55 detected from the ammeter 34 and the rotation angle of the pump drive motor 55 detected from the resolver 35. To do. Note that the resolver 35 is not necessarily provided.

  When the first master cut valve 52A and the second master cut valve 52B are opened, the brake fluid discharged from the first pump 56A and the second pump 56B is the master cut valve 52, the first brake fluid reservoir 57A, It circulates between 2 brake fluid reservoirs 57B. For this reason, the master cut valve differential pressure does not occur. On the other hand, when a control current is supplied to the first master cut valve 52A and the second master cut valve 52B and these opening degrees are reduced, a master cut valve differential pressure is generated. As a result, the brake fluid pressure acting on the braking force generating means 41FR, 41RL, 41FL, 41RR can be increased more than the brake fluid pressure in the master cylinder 44.

  FIG. 3 is a flowchart showing a procedure of braking control according to the present embodiment. 4A and 4B are schematic diagrams illustrating a state where the vehicle is stopped at a gradient. 5 and 6 are timing charts of the braking control according to the present embodiment. FIG. 7 is a schematic diagram showing a data map describing control parameters used for braking control according to the present embodiment. The drive control according to the present embodiment is executed by the braking control device 1. First, the control when the vehicle 100 stops will be described.

  Since the vehicle 100 shown in FIG. 1 uses the electric motor 60 as a power generation source, regenerative braking is possible. In other words, the electric motor 60 can be used as a generator, and the vehicle 100 can be braked by converting the kinetic energy of the vehicle 100 into electric energy. In the braking control according to the present embodiment, the regenerative braking force applied to the driving wheels (wheels 10FL, 10FR) of the vehicle 100 and the friction braking force applied to the driving wheels and driven wheels (wheels 10RL, 10RR) of the vehicle 100, that is, mechanical The sum of the braking force generated by the expression brake is set to a braking force required by the driver of the vehicle 100 (hereinafter referred to as a required braking force). This is called regenerative cooperative control.

  It is assumed that at time t = t0 shown in FIG. 5, a braking request is made to the vehicle 100 traveling at the vehicle speed V1, that is, the driver of the vehicle 100 depresses the brake pedal 20. When the brake pedal 20 is operated, the control condition determination unit 1d of the braking control device 1 calculates the required braking force Fb_d based on the pedal operation detected by the stroke sensor 32 or the pedaling force detection switch 33.

  When the vehicle 100 is in a normal running state, the brake actuator 50 is configured such that the master cut valve 52 is opened, the holding solenoid valves 53FR, 53RL, 53FL, 53RR are opened, and the decompression solenoid valves 54FR, 54RL, 54FL, 53RR are closed. It is in a state of being spoken. In this state, the brake fluid pressure of the same magnitude as the brake fluid pressure generated in the brake fluid in the master cylinder 44 when the driver depresses the brake pedal 20 is applied to the braking force generators 41FR, 41RL, 41FL, 41RR. Acts on the wheel cylinder. At this time, the braking force generated in the vehicle 100 is set as a master pressure braking force Fb_m.

  The braking / driving force calculation unit 1a of the braking control device 1 sets a value obtained by subtracting the master pressure braking force Fb_m from the required braking force Fb_d as the regenerative braking force Fb_r. Then, the braking / driving force calculation unit 1a transmits information about the regenerative braking force Fb_r to the drive control ECU 2. Based on the information on the regenerative braking force Fb_r, the drive control ECU 2 sends a drive signal for the electric motor 60 so that the regenerative braking force applied to the drive wheels (wheels 10FL, 10FR) of the vehicle 100 by the electric motor 60 becomes the regenerative braking force Fb_r. Generate. Then, the drive control ECU 2 transmits the drive signal to the power conversion device 3 and controls the electric motor 60 by the power conversion device 3. As a result, the electric motor 60 is driven from the drive wheels (wheels 10FL, 10FR) of the vehicle 100 with the regenerative torque Tm to generate electric power. This electric power is stored in the battery 4 via the power conversion device 3.

  Thereafter, the vehicle speed of the vehicle 100 gradually decreases due to the sum of the regenerative braking force Fb_r and the master pressure braking force Fb_m. When the vehicle speed becomes equal to or lower than the reference vehicle speed V2 at time t = t1 shown in FIG. 1 braking device control part 1f performs replacement control. The switching control refers to the brake fluid pressure of the brake fluid obtained by pressurizing the regenerative braking force Fb_r by the first pump 56A and the second pump 56B of the brake actuator 50 shown in FIG. 2 as the braking force generators 41FR, 41RL, 41FL, In this control, the pump pressure braking force Fb_p generated by acting on the wheel cylinder of 41RR is replaced. Since the regenerative braking force Fb_r decreases as the vehicle speed of the vehicle 100 decreases due to the characteristics of the electric motor 60, such replacement control is necessary.

  In order to start the smooth switching control at time t = t1, the braking device controller 1f starts driving the first pump 56A and the second pump 56B before time t = t1, and sets the pump rotation speed to a predetermined value. It is preferable to increase the rotational speed to N1. When the first pump 56A and the second pump 56B are rotated, the master cut valve differential pressure ΔP_SMC is reduced by reducing the opening of the first master cut valve 52A and the second master cut valve 52B. appear. As a result, the brake fluid pressure acting on the wheel cylinders of the braking force generating means 41FR, 41RL, 41FL, 41RR can be increased more than the brake fluid pressure in the master cylinder 44.

  The braking / driving force calculation unit 1a transmits a command to the drive control ECU 2, and gradually decreases the value of the regenerative braking force Fb_r. Then, the master cut valve differential pressure ΔP_SMC is set so that the decrease in the regenerative braking force Fb_r is compensated by the pump pressurizing braking force Fb_p. In the present embodiment, the master cut valve differential pressure ΔP_SMC is increased to the target differential pressure ΔP0.

  It is assumed that the switching control from the regenerative braking force Fb_r to the pump pressurizing braking force Fb_p is completed (when the regenerative torque Tm in FIG. 5 is 0) and the vehicle 100 is stopped. At this time, the vehicle speed of the vehicle 100 becomes zero. Here, unlike the so-called electronically controlled brake system, the brake actuator 50 does not block the communication between the master cylinder 44 and the wheel cylinders of the braking force generating means 41FR, 41RL, 41FL, 41RR, and the wheel cylinder 50 The braking force is controlled in a state in which the brake fluid can be supplied.

  For this reason, if the driver stops the first pump 56A and the second pump 56B while operating the brake pedal 20, the flow force of the brake fluid passing through the master cut valve 52 decreases, and the fluid force May decrease and the opening degree of the master cut valve 52 may increase. As a result, the brake fluid flowing into the master cylinder 44 through the master cut valve 52 increases, and a phenomenon of pushing back the brake pedal 20 to the driver side occurs, which may reduce the operational feeling of the brake pedal 20. .

  Therefore, in the braking control according to the present embodiment, when the first pump 56A and the second pump 56B are stopped, the pressure difference between the brake fluid pressure at the outlet of the master cut valve 52 and the brake fluid pressure at the inlet (that is, (Master cut valve differential pressure) is increased more than before the first pump 56A and the second pump 56B are stopped. More specifically, the braking device controller 1f stops the first pump 56A and the second pump 56B when the vehicle 100 stops, that is, at time t = ts. Then, at time t = t2, the first pump 56A and the second pump 56B are completely stopped. When stopping the first pump 56A and the second pump 56B, the brake fluid pressure calculation unit 1c of the braking control device 1 sets the target value of the master cut valve 52 to ΔP2 higher than the current master cut valve differential pressure ΔP0. Set to. Then, the braking device control unit 1f controls the master cut valve 52 so that the master cut valve differential pressure ΔP_SMC becomes ΔP2 at time t = ts.

  Thereby, the force in the direction of closing the master cut valve 52 cancels out the force in the direction of increasing the opening degree of the master cut valve 52, and the fluctuation of the opening degree of the master cut valve 52 can be suppressed. As a result, the phenomenon that the brake fluid flows into the master cylinder 44 through the master cut valve 52 can be suppressed, so that the phenomenon that the brake pedal 20 is pushed back to the driver side can be suppressed. And the fall of the operation feeling of the brake pedal 20 is suppressed.

  Further, when the opening degree of the master cut valve 52 increases, the brake fluid pressure acting on the wheel cylinder also decreases. However, since the brake control according to the present embodiment can suppress the phenomenon that the brake fluid flows into the master cylinder 44 through the master cut valve 52, it is possible to suppress the decrease in the brake fluid pressure acting on the wheel cylinder.

  Next, braking control after t = t2 in FIG. 5 will be described. In the braking control according to the present embodiment, after the first pump 56A and the second pump 56B are stopped, the master cut valve differential pressure ΔP_SMC is held at a predetermined value greater than zero.

  Thereby, even after the first pump 56A and the second pump 56B are stopped, it is possible to suppress a decrease in brake fluid pressure acting on the wheel cylinder. As a result, for example, even when the vehicle 100 is stopped on an ascending or descending slope, the vehicle 100 can be reliably stopped. At the same time, a decrease in the operational feeling of the brake pedal 20 is suppressed.

  In this case, after the first pump 56A and the second pump 56B are stopped, the pressure of the brake fluid between the master cut valve 52 and the braking force generation means 41FR, 41RL, 41FL, 41RR becomes a value larger than 0. Retained. For example, when the vehicle 100 is stopped at a slope, the predetermined value is a magnitude of the brake fluid pressure that can generate a braking force that can stop the vehicle 100 at the slope. Next, the contents of this control will be described.

  In step S <b> 101, the braking / driving force calculation unit 1 a of the braking control device 1 generates a brake hydraulic pressure (hereinafter referred to as a braking force set to generate a braking force set based on the previous value F_last_break of the required braking force and the state of the vehicle 100. The previous value P_last_smc of the command brake fluid pressure is stored in the storage unit 1m. Here, the last time means a control routine immediately before the current control routine.

  Proceeding to step S102, the braking / driving force calculation unit 1a obtains the current required braking force F_break. The braking / driving force calculation unit 1a acquires information from the master cylinder pressure sensor 31, the stroke sensor 32, or the treading force detection switch 33, and obtains a required braking force based on these information. Next, in step S103, the braking / driving force calculation unit 1a obtains the current driving force (vehicle driving force) F_drive of the vehicle. The braking / driving force calculation unit 1a obtains the torque command value of the electric motor 60 from the drive control ECU 2 shown in FIG. 1, the rotation speed per unit time (motor rotation speed), the radius of the wheels 10FL and 10FR of the vehicle 100 as drive wheels, and the like. The vehicle driving force F_drive is obtained from these information.

  Next, in step S104, the road surface gradient calculation unit 1b of the braking control device 1 obtains information (road surface gradient information) α indicating the road surface gradient (road surface gradient) on which the vehicle 100 is traveling or stopped. As shown in FIGS. 4A and 4B, in the present embodiment, the road surface gradient information α is an inclination angle (road surface inclination angle) of the road surface S with respect to the horizontal line Hz. The road surface gradient information α may use the ratio of the distance in the vertical direction to the distance in the horizontal direction. The road surface gradient calculation unit 1 b obtains road surface gradient information α based on the information acquired from the inclination angle sensor 37.

  Here, when the front f of the vehicle 100 faces a higher inclination, the road surface S on which the vehicle 100 is traveling or stopped is an uphill, and the front f of the vehicle 100 faces a lower inclination. The road surface S on which the vehicle 100 is traveling or stopped has a downward slope.

  Next, proceeding to step S105, the braking / driving force calculating unit 1a obtains a force (gradient stopping force during non-driving) F_α required to stop the vehicle 100 without the driving force on a road surface with a gradient. As shown in FIGS. 4A and 4B, the magnitude of the non-driving gradient stopping force F_α is that of the mass M in the direction parallel to the road surface S, where M is the mass of the vehicle and g is the acceleration of gravity. It is equal to the component force Fd. That is, F_α = Fd = M × g × sin α. As shown in FIG. 4A, when the road surface S on which the vehicle 100 is traveling or stopped has an upward slope, F_α is a positive value, and as shown in FIG. 4B, the vehicle 100 travels. Alternatively, when the stopped road surface S has a downward slope, F_α is a negative value.

  Next, proceeding to step S106, the brake fluid pressure calculation unit 1c of the braking control device 1 obtains a brake fluid pressure (gradient stop brake fluid pressure) P_act necessary for stopping the vehicle 100 on a road surface with a gradient. The gradient stop brake hydraulic pressure P_act is the pressure of the wheel cylinder that constitutes the braking force generation means 41FL, 41FR, 41RL, 41RR shown in FIG. 1, and for example, the pressure on the outlet side of the master cut valve 52 is the wheel pressure. Considered as cylinder pressure.

  In determining the gradient stop brake fluid pressure P_act, first, the brake fluid pressure calculation unit 1c first determines the gradient stop force that is the difference between the no-drive gradient stop force F_α determined in step S105 and the vehicle drive force F_drive determined in step S103. F_s (= F_α−F_drive) is obtained. For example, when there is no driving force of the vehicle 100 in an ascending gradient, the gradient stopping force F_s is equal to the non-driving gradient stopping force F_α, but when the vehicle 100 has a driving force (for example, creep force), the gradient stopping force F_s is Accordingly, the non-drive-time gradient stopping force F_α becomes smaller by that amount.

  If the gradient stopping force F_s thus obtained is applied to the vehicle 100, the vehicle 100 can be stopped on a road surface with a gradient. Since the gradient stopping force F_s is a force acting on the vehicle 100, the gradient stopping force F_s is generated by the braking force of the braking force generation means 41FL, 41FR, 41RL, 41RR provided in the vehicle 100. For this reason, the brake fluid pressure calculation unit 1c obtains the brake fluid pressure necessary for the braking force generation means 41FL, 41FR, 41RL, 41RR to generate the gradient stop force F_s, that is, the gradient stop brake fluid pressure P_act.

  For example, the pressure receiving areas of the wheel cylinders of the wheels 10FL, 10FR, 10RL, and 10RR included in the vehicle 100 include the braking force F_sp (the sum is F_s), the radius R, and the braking force generation means 41FL, 41FR, 41RL, and 41RR. It is determined based on As, the radius r of the disc rotor, the friction coefficient μ between the brake pad and the disc rotor, and the like.

  Note that the gradient stop brake fluid pressure P_act is 0 or more because the gradient stop brake fluid pressure P_act does not take a negative value. Therefore, when the gradient stop brake hydraulic pressure P_act obtained based on the gradient stop force F_s becomes a negative value, the gradient stop brake hydraulic pressure P_act = 0. Further, since the gradient stopping force F_s has a negative value in the downward gradient, the gradient stopping brake hydraulic pressure P_act is set to a positive value when the gradient stopping brake hydraulic pressure P_act is obtained.

  When the gradient stop brake hydraulic pressure P_act is obtained, the process proceeds to step S107. In step S107, the control condition determination unit 1d of the braking control device 1 determines whether or not the accelerator 38P shown in FIG. 1 is OFF (the accelerator 38P is not stepped on, that is, the accelerator opening is 0). This is determined based on the information acquired by the control condition determination unit 1d from the accelerator opening sensor 38 connected to the drive control ECU 2.

  When it is determined Yes in step S107, that is, when the control condition determining unit 1d determines that the accelerator is OFF, in step S108, the control condition determining unit 1d determines whether or not the brake is ON. . This is determined by whether or not there is an operation on the brake pedal 20 shown in FIG. The control condition determination unit 1d determines whether the brake is ON based on information acquired from the master cylinder pressure sensor 31, the stroke sensor 32, and the pedaling force detection switch 33.

  If it is determined Yes in step S108, that is, if the control condition determination unit 1d determines that the brake is ON, in step S109, the brake hydraulic pressure reduction parameter calculation unit 1e of the braking control device 1 operates the vehicle 100. The amount by which the person releases the brake (brake return amount) ΔF_dec1 is obtained. The brake return amount ΔF_dec1 is the larger of the difference between the previous value F_last_break of the required braking force stored in step S101 and the current required braking force F_break obtained in step S102, and 0. That is, ΔF_dec1 = max (F_last_break−F_break, 0). Here, ΔF_dec1 is a force.

  When F_last_break-F_break is positive, that is, when the current required braking force is smaller than the previous F_last_break-F_break, the depression amount of the brake pedal 20 is decreased. In this case, ΔF_dec1 = F_last_break−F_break. On the other hand, when F_last_break-F_break is negative, that is, when the required braking force at the current time is larger than the previous F_last_break-F_break, the amount of depression of the brake pedal 20 is increased. In this case, ΔF_dec1 = 0.

  Next, in step S110, the brake fluid pressure calculation unit 1c obtains the current instruction brake fluid pressure P_smc. In obtaining the current command brake fluid pressure P_smc, the brake fluid pressure calculation unit 1c converts the brake return amount ΔF_dec1 obtained in step S109 into the brake fluid pressure (brake return brake fluid pressure) ΔP_dec1. The brake return brake hydraulic pressure ΔP_dec1 is, for example, a brake return amount ΔF_dec1_p (total is ΔF_dec1) corresponding to each of the wheels 10FL, 10FR, 10RL, and 10RR included in the vehicle 100, a radius R, a braking force generation unit 41FL, 41FR, and 41RL. , 41RR wheel cylinder pressure receiving area As, disk rotor radius r, friction coefficient μ between the brake pad and disk rotor, and the like.

  Next, the brake fluid pressure calculation unit 1c calculates the difference between the previous value P_last_smc of the command brake fluid pressure acquired in step S101 and the brake return brake fluid pressure ΔP_dec1 and the gradient stop brake fluid pressure P_act obtained in step S106. The larger one is set as the command brake hydraulic pressure P_smc at the present time. That is, P_smc = max (P_last_smc−ΔP_dec1, P_act). As described above, the current command brake fluid pressure P_smc is a value obtained by subtracting the brake return amount from the previous command brake fluid pressure, but is not smaller than the gradient stop brake fluid pressure P_act. As a result, the brake can be released in accordance with the operation of the brake pedal 20, so that the brake operation feeling becomes natural, and the vehicle 100 is traveling on the slope or stopped on the slope (that is, when the vehicle 100 is on a slope). ), It is possible to suppress a decrease in the operational feeling of the brake pedal. Further, even when the vehicle 100 is traveling on the slope or is stopped on the slope, the vehicle 100 can be stopped more reliably.

  When the current command brake fluid pressure P_smc is obtained, the brake device controller 1f of the brake control device 1 determines that the brake fluid pressure acting on the wheel cylinders of the braking force generating means 41FL, 41FR, 41RL, 41RR is the current command brake. The opening degree of the master cut valve 52 is adjusted so that the hydraulic pressure P_smc is obtained. In this case, the braking device control unit 1f may perform feedback control on the opening degree of the master cut valve 52 so that the first outlet brake fluid pressure sensor 36A and the second outlet brake fluid pressure sensor 36B become P_smc. . Further, the relationship between the opening of the master cut valve 52 and the brake fluid pressure acting on the wheel cylinder of the outlet side of the master cut valve 52, that is, the braking force generating means 41FL, 41FR, 41RL, 41RR is obtained. Based on this, the opening degree of the master cut valve 52 may be adjusted.

  When the braking device controller 1f adjusts the opening degree of the master cut valve 52, the process proceeds to step S115. In step S115, the control condition determination unit 1d determines whether or not the current instruction brake fluid pressure P_smc obtained in step S110 is zero. When it determines with Yes at step S115, ie, when the control condition determination part 1d determines with P_smc = 0, the braking control which concerns on this embodiment is complete | finished. When it is determined No in step S115, that is, when the control condition determining unit 1d determines that P_smc> 0, the process returns to step S101, and the next control routine is started.

  By repeating Steps S101 to S115, the command brake fluid pressure P_smc at the present time approaches the gradient stop brake fluid pressure P_act. As a result, the master cut valve differential pressure ΔP_SMC decreases as indicated by A in FIG. 5 (t = t2 to t4). That is, the master cut valve differential pressure ΔP_SMC approaches the differential pressure ΔP1 corresponding to the gradient stop brake hydraulic pressure P_act.

  When it is determined No in step S107 or step S108, that is, when the control condition determination unit 1d determines that the accelerator is ON or the brake is OFF, the vehicle 100 is about to stop or start from the stop. It can be judged that it is in a state. In this case, the process proceeds to step S111, and the control condition determination unit 1d determines whether or not the road surface gradient information α (road surface inclination angle in the present embodiment) obtained in step S104 is greater than zero.

  When it is determined Yes in step S111, that is, when the control condition determination unit 1d determines that α> 0, the vehicle 100 is stopped on an ascending road surface (after t = t4 shown in FIG. 5). Or it can be determined that the vehicle is going to start from a stop. In this case, the process proceeds to step S112, and the brake hydraulic pressure calculation unit 1c sets the current indicated brake hydraulic pressure P_smc as the gradient stop brake hydraulic pressure P_act obtained in step S106.

  When the command brake fluid pressure P_smc at the current time is obtained, the braking device control unit 1f determines that the brake fluid pressure acting on the wheel cylinders of the braking force generation means 41FL, 41FR, 41RL, 41RR becomes the command brake fluid pressure P_smc at the current time. Thus, the opening degree of the master cut valve 52 is adjusted. As a result, even when the vehicle 100 is stopped on an upward slope, the brake fluid pressure acting on the wheel cylinders of the braking force generation means 41FL, 41FR, 41RL, 41RR is maintained at the gradient stop brake fluid pressure P_act. Can be stopped more reliably.

  Next, the process proceeds to step S115. Since step S115 has been described above, the description thereof will be omitted. If the vehicle 100 is to be started by depressing the accelerator 38P, the vehicle driving force F_drive in step S103 increases. As a result, the gradient stop brake fluid pressure P_act obtained in step S106 at a certain point in time becomes a negative value. However, as described above, in this case, the gradient stop brake fluid pressure P_act = 0, so step S112 The command brake hydraulic pressure P_smc at becomes zero. If P_smc = 0, it is determined Yes in step S115, and the braking control according to the present embodiment ends.

  When it is determined No in step S111, that is, when the control condition determining unit 1d determines that P_act ≦ 0, the vehicle 100 is stopped on a downhill road surface (until t = t5 shown in FIG. 6). Period) or whether the vehicle is about to start from a stop. In this case, the process proceeds to step S113, and the brake fluid pressure reduction parameter calculation unit 1e obtains a brake fluid pressure reduction gradient ΔP_dec2.

  The depressurization gradient ΔP_dec2 is used when releasing the braking force of the vehicle 100 stopped at a descending gradient at least by depressurizing the brake fluid pressurized by the first pump 56A and the second pump 56B included in the brake actuator 50. This is the parameter to use. In this case, the depressurization gradient ΔP_dec2 determines the depressurization speed of the brake fluid. As the gradient of the road surface on which the vehicle 100 is stopped increases, the depressurization gradient of the brake fluid in the brake actuator 50 decreases. Set to do. This will be described later.

  When the pressure reduction gradient ΔP_dec2 is obtained, the process proceeds to step S114, and the brake fluid pressure calculation unit 1c obtains the command brake fluid pressure P_smc at the current time. In determining the command brake fluid pressure P_smc at the current time point, the brake fluid pressure calculation unit 1c determines that the difference between the previous value P_last_smc of the command brake fluid pressure acquired in step S101 and the pressure reduction gradient ΔP_dec2 determined in step S113 is 0. The larger one is set as the command brake hydraulic pressure P_smc at the present time. That is, P_smc = max (P_last_smc−ΔP_dec2, 0). In this way, the current command brake fluid pressure P_smc is a value obtained by subtracting the pressure reduction gradient ΔP_dec2 from the previous command brake fluid pressure, but is not smaller than zero.

  Since P_smc = max (P_last_smc−ΔP_dec2, 0), the speed at which the brake fluid in the brake actuator 50 is reduced can be reduced by reducing the pressure reduction gradient ΔP_dec2. In the present embodiment, as shown in the data map 70 of FIG. 7, as the road surface gradient information α shown on the horizontal axis increases, that is, the road surface inclination angle (detected by the inclination angle sensor 37 that is a road surface inclination detection unit, The depressurization gradient ΔP_dec2 is set to be smaller as the gradient of the road surface on which the vehicle 100 is stopped or traveling is increased. As a result, the speed at which the brake fluid in the brake actuator 50 is depressurized can be reduced as the road surface inclination angle of the road surface (slope) on which the vehicle 100 is stopped increases, that is, as the road surface gradient increases.

  In this way, by setting the command brake hydraulic pressure P_smc at the present time, when the vehicle 100 is going to start from a state where the vehicle 100 is stopped on a downward slope, the braking force of the vehicle 100 is further increased as the road surface slope increases. It is released gently. As a result, the vehicle 100 is more reliably stopped, and the vehicle 100 behaves as intended by the driver when stopped.

  When the command brake fluid pressure P_smc at the current time is obtained, the braking device control unit 1f determines that the brake fluid pressure acting on the wheel cylinders of the braking force generation means 41FL, 41FR, 41RL, 41RR becomes the command brake fluid pressure P_smc at the current time. Thus, the opening degree of the master cut valve 52 is adjusted (t = t5 in FIG. 6). Then, as shown by B in FIG. 6, the master cut valve differential pressure ΔP_SMC decreases between t = t5 and t6, so that the brake hydraulic pressure on the outlet side of the master cut valve 52 in the brake actuator 50 decreases. As a result, the braking force of the vehicle 100 is gradually released, so that sudden jumping out of the vehicle 100 is suppressed.

  As described above, the depressurization gradient ΔP_dec2 is set to be smaller as the gradient increases, so that the gradient indicated by B in FIG. 6 becomes gentler as the gradient increases, and the time between t = t5 and t6 becomes longer. Become. As a result, the braking force of the vehicle 100 is gradually released as the gradient increases, so that sudden jump-out of the vehicle 100 can be more reliably suppressed, and safety is further improved. Next, the process proceeds to step S115. In step S115, if the current command brake fluid pressure P_smc obtained in step S114 is larger than 0 (step S115: No), the next control routine is entered, and when the current command brake fluid pressure P_smc becomes 0, the present The braking control according to the embodiment ends.

  Here, the above-described step S112 is a procedure for obtaining the command brake hydraulic pressure P_smc at the present time when it is determined that the vehicle 100 is either stopped on an ascending road surface or is about to start from the stop. It is. In this procedure, the command brake hydraulic pressure P_smc at the present time may be obtained using the above-described pressure reduction gradient ΔP_dec2.

  In step S112, when determining the current command brake fluid pressure P_smc using the pressure decrease gradient ΔP_dec2, the brake fluid pressure calculation unit 1c calculates the previous value P_last_smc of the command brake fluid pressure acquired in step S101 and the pressure decrease calculated in step S113. The larger one of the difference from the gradient ΔP_dec2 and the gradient stop brake hydraulic pressure P_act obtained in step S106 is set as the current indicated brake hydraulic pressure P_smc. That is, P_smc = max (P_last_smc−ΔP_dec2, P_act). Thus, the current command brake fluid pressure P_smc is a value obtained by subtracting the pressure reduction gradient ΔP_dec2 from the previous command brake fluid pressure, but is not smaller than P_act. As a result, when the vehicle 100 is parked on an ascending slope, the minimum brake fluid pressure acting on the wheel cylinders of the braking force generating means 41FL, 41FR, 41RL, 41RR is the gradient stop brake fluid pressure P_act. In addition to stopping the vehicle 100 more reliably, the vehicle 100 will behave as intended by the driver.

  Since P_smc = max (P_last_smc−ΔP_dec2, 0), the speed at which the brake fluid in the brake actuator 50 is reduced can be reduced by reducing the pressure reduction gradient ΔP_dec2. In the present embodiment, as shown in the data map 70 of FIG. 7, the pressure gradient ΔP_dec2 is set to decrease as the road surface gradient information α shown on the horizontal axis increases, that is, as the road surface inclination angle increases. To do. As a result, the speed at which the brake fluid in the brake actuator 50 is depressurized can be reduced as the road surface inclination angle of the road surface (slope) on which the vehicle 100 is stopped increases, that is, as the road surface gradient increases.

  In this way, by setting the command brake hydraulic pressure P_smc at the present time, when the vehicle 100 is going to start from a state where the vehicle 100 is stopped on an upward slope, the braking force of the vehicle 100 increases as the road surface slope increases. It is released gently. As a result, the vehicle 100 can be reliably prevented from sliding down, so that safety is improved.

  As described above, in this embodiment, the flow rate control valve is provided on the brake fluid passage between the master cylinder and the braking force generating means. The flow control valve increases the gradient when the braking force of the vehicle stopped on the slope (uphill or downhill) is released by reducing the pressure of the brake fluid pressurized by the pump. Therefore, the speed at which the brake fluid is decompressed is reduced. As a result, even when the vehicle is stopped on an uphill or downhill, the brake fluid pressure acting on the braking force generating means is gradually released, so that the vehicle can be stopped more reliably and the driver's intention You can move the vehicle on the street. Also, as the road surface gradient increases, the speed at which the braking force is released decreases, so even if the road surface gradient increases, the vehicle can be stopped more reliably and the vehicle as intended by the driver. Can be moved.

  Further, a brake device is used which is provided with a flow rate control valve between the master cylinder and the braking force generating means and supplies brake fluid discharged by the pump to the braking force generating means by adjusting the opening of the flow rate control valve. Therefore, the cost can be reduced as compared with a so-called by-wire brake system.

  Further, in the present embodiment, the flow control valve maintains the brake fluid pressure of the brake fluid between the flow control valve and the braking force generating means at a predetermined pressure greater than 0 after the vehicle stops. In this case, the predetermined pressure is preferably a magnitude of the brake fluid pressure that generates a braking force sufficient to allow the vehicle to remain on the road surface. For example, when the vehicle stops on an inclined road surface, the brake fluid pressure is set so as to generate a braking force sufficient to allow the vehicle to remain on the inclined road surface. In this way, the brake fluid pressure of the brake fluid between the flow control valve and the braking force generating means is adjusted in consideration of the state of the vehicle, so that the vehicle can be stopped reliably. At the same time, a decrease in the brake pedal operation feeling is suppressed.

  As described above, the control device for a braking device according to the present invention is useful for a braking device for a vehicle, and particularly suitable for suppressing a decrease in the operation feeling of a brake pedal when the vehicle is at least on a slope. ing.

It is a mimetic diagram showing the vehicles by which the brake equipment concerning this embodiment is carried. It is an apparatus block diagram which shows the structure of the brake actuator with which the braking device which concerns on this embodiment is provided. It is a flowchart which shows the procedure of the braking control which concerns on this embodiment. It is a schematic diagram which shows the state which the vehicle has stopped on the gradient. It is a schematic diagram which shows the state which the vehicle has stopped on the gradient. It is a timing chart of braking control concerning this embodiment. It is a timing chart of braking control concerning this embodiment. It is a schematic diagram which shows the data map which described the control parameter used for the brake control which concerns on this embodiment.

Explanation of symbols

1 Braking control device (braking device control device)
1b Road surface gradient calculation unit 1c Brake hydraulic pressure calculation unit 1d Control condition determination unit 1e Brake hydraulic pressure reduction parameter calculation unit 1a Braking / driving force calculation unit 1f Braking device control unit 1m Storage unit 2 Drive control ECU
DESCRIPTION OF SYMBOLS 3 Power converter 4 Battery 10FL, 10FR, 10RL, 10RR Wheel 20 Brake pedal 31 Master cylinder pressure sensor 32 Stroke sensor 33 Treading force detection switch 36A 1st exit side brake fluid pressure sensor 36B 2nd exit side brake fluid pressure sensor 37 Inclination angle Sensor 38 Accelerator opening sensor 41FL, 41FR, 41RL, 41RR Braking force generating means 42FL Braking force generating means side brake fluid piping 43 Brake booster 44 Master cylinder 45A Master cylinder side first brake fluid piping 45B Master cylinder side second brake fluid piping DESCRIPTION OF SYMBOLS 50 Brake actuator 51A 1st hydraulic pressure transmission system 51B 2nd hydraulic pressure transmission system 52A 1st master cut valve 52B 2nd master cut valve 52 Master cut valve 55 Pump drive motor 56A First pump 56B Second pump 58A First high-pressure brake fluid piping 58B Second high-pressure brake fluid piping 60 Electric motor 61 Transmission 62FR Right front drive shaft 62FL Left front drive shaft 70 Data map 100 Vehicle 101 Braking device 102 Drive device

Claims (4)

Braking force generating means for generating braking force on wheels provided in the vehicle by supplying brake fluid;
A master cylinder that generates brake fluid pressure in accordance with the depressing force from the brake pedal;
A pump that pressurizes the brake fluid and supplies the brake fluid pressurized to the brake fluid passage from the master cylinder to the braking force generating means;
A control device for a braking device comprising: a flow rate control valve provided on the brake fluid passage between the master cylinder and the braking force generating means;
Road surface gradient detecting means for detecting the gradient of the road surface on which the vehicle is running or stopped;
When the braking force of the vehicle stopped on the slope is released by controlling the flow rate control valve to reduce the brake fluid pressurized by the pump, the road surface gradient detecting means detects A flow rate control valve control means for reducing the speed at which the brake fluid is depressurized as the gradient increases;
A control device for a braking device comprising: The flow control valve control means includes
The pressure difference between the pressure of the brake fluid at the outlet of the flow control valve and the pressure of the brake fluid at the inlet when the pump is stopped is increased as compared to before the pump is stopped. The control device for a braking device according to claim 1. The flow control valve control means includes
The pressure of the brake fluid between the flow control valve and the braking force generation means is maintained at a predetermined value greater than 0 after the pump is stopped. Control device for braking device. The flow control valve control means includes
When the vehicle stops at a slope, the pressure of the brake fluid between the flow control valve and the braking force generation means is necessary for the braking force generation means to stop the vehicle at the slope. The control device for a braking device according to claim 1, wherein the control device maintains a pressure higher than a pressure necessary for generating a braking force.

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