JP5821830B2 - Braking force control device and control device - Google Patents

Description

  The present invention relates to a braking force control device and a control device.

  As a conventional braking force control device and control device mounted on a vehicle, for example, Patent Document 1 discloses pressure control used for control for braking purposes such as antilock control, traction control, braking effect control, etc. in a vehicle. An apparatus is disclosed. This pressure control device removes a component having the same frequency as the resonance frequency of one of a plurality of vibration elements that vibrate based on the pressure wave of the vehicle from the pressure wave of the electromagnetic valve device based on the supply of the pulse current. This is to reduce vehicle interior noise.

JP-A-5-097026

  Incidentally, the pressure control device described in Patent Document 1 described above has room for further improvement in terms of appropriate noise reduction with a simpler configuration, for example.

  This invention is made | formed in view of said situation, Comprising: It aims at providing the braking force control apparatus and control apparatus which can suppress abnormal noise appropriately.

  In order to achieve the above object, a braking force control device according to the present invention includes a master cylinder that applies an operating pressure to a working fluid in accordance with an operating force input to a braking operation member, and a braking pressure based on the operating pressure. A brake having a wheel cylinder that generates a braking force generated on a wheel of the vehicle by the action of an actuator, and an actuator that can adjust the braking force generated on the wheel by adjusting the braking pressure supplied to the wheel cylinder In combination with the device and the increase and maintenance of the braking pressure, the linear valve of the actuator is controlled at the time of ABS operation that controls the slip state of the wheel by controlling the actuator and adjusting the braking pressure. A control device capable of executing linear pulse pressure increasing control for increasing the braking pressure, and the control device is configured to operate the ABS during the ABS operation. And the target pressure difference between the operating pressure and the braking pressure, on the basis of said brake pressure of the target, and wherein the determining the presence or absence of the linear pulse pressure increase control of the execution.

  In the braking force control device, the control device has a target differential pressure larger than a preset control permission differential pressure, and a change amount of the target braking pressure is within a preset control permission range. In the case where the linear pulse pressure increase control is executed and the target differential pressure is equal to or less than a preset control permission differential pressure, or a control permission range in which the amount of change in the target braking pressure is preset When it is outside, the linear pulse pressure increase control may not be executed.

  In the braking force control device, the control permission differential pressure causes an abnormal noise due to an increase in the flow rate of the working fluid when the differential pressure between the operation pressure and the braking pressure is adjusted. The control permission range is set in accordance with a differential pressure having a fearful magnitude, and abnormal noise may occur due to an increase in the flow rate of the working fluid in the actuator when the braking pressure is increased. A lower limit is set according to the pressure increase gradient, and an upper limit is set according to the pressure increase gradient that may cause a large difference between the target braking pressure and the actual braking pressure at the end of the control, thereby degrading controllability. Can be.

  In order to achieve the above object, a control device according to the present invention includes a master cylinder that applies an operating pressure to a working fluid according to an operating force input to a braking operation member, and a braking pressure based on the operating pressure. A braking device having a wheel cylinder that generates a braking force generated on a wheel of the vehicle, and an actuator that can adjust the braking force generated on the wheel by adjusting the braking pressure supplied to the wheel cylinder. A control device that controls the actuator to adjust the braking pressure to control the slip state of the wheel, during ABS operation, to control the linear valve of the actuator to increase and maintain the braking pressure; The linear pulse pressure increase control for increasing the braking pressure can be executed by combining the operation pressure and the control during the ABS operation. And the target pressure difference between the pressure, on the basis of said brake pressure of the target, and wherein the determining the presence or absence of the linear pulse pressure increase control of the execution.

  The braking force control device and the control device according to the present invention have an effect that noise can be appropriately suppressed.

FIG. 1 is a schematic configuration diagram of a vehicle to which a braking force control device according to an embodiment is applied. FIG. 2 is a schematic configuration diagram illustrating an example of a VSC actuator of the braking force control apparatus according to the embodiment. FIG. 3 is a diagram illustrating an example of linear pulse pressure increase control in the braking force control apparatus according to the embodiment. FIG. 4 is a diagram illustrating controllability in linear pulse pressure increase control. FIG. 5 is a flowchart illustrating an example of control by the ECU according to the embodiment.

  Embodiments according to the present invention will be described below in detail with reference to the drawings. In addition, this invention is not limited by this embodiment. In addition, constituent elements in the following embodiments include those that can be easily replaced by those skilled in the art or those that are substantially the same.

[Embodiment]
FIG. 1 is a schematic configuration diagram of a vehicle to which a braking force control device according to an embodiment is applied. FIG. 2 is a schematic configuration diagram illustrating an example of a VSC actuator of the braking force control apparatus according to the embodiment. FIG. 3 is a diagram illustrating an example of linear pulse pressure increase control in the braking force control apparatus according to the embodiment. FIG. 4 is a diagram illustrating controllability in linear pulse pressure increase control. FIG. 5 is a flowchart illustrating an example of control by the ECU according to the embodiment.

  The braking force control apparatus 1 of this embodiment is a system for controlling the vehicle 2 mounted on the vehicle 2 as shown in FIG. 1. Typically, the braking force generated on the wheels 3 of the vehicle 2 is generated. It is a system which controls the slip state of each wheel 3 by controlling and stabilizes the behavior of the vehicle 2. The vehicle 2 includes a left front wheel 3FL, a right front wheel 3FR, a left rear wheel 3RL, and a right rear wheel 3RR as the wheels 3, but these are simply referred to as wheels 3 when it is not necessary to separate them.

  Specifically, the vehicle 2 includes a braking force control device 1, an accelerator pedal 4, a power source 5, and the like. The braking force control device 1 includes a brake pedal 6, a braking device 7, an ECU 8 as a control device, and the like. In the vehicle 2, the power source 5 generates power (torque) according to the operation of the accelerator pedal 4 by the driver, and this power is transmitted to the wheels 3 via a power transmission device (not shown). Generate driving force. In addition, the vehicle 2 generates a braking force on the wheel 3 by operating the braking device 7 according to the operation of the brake pedal 6 by the driver.

  The power source 5 is a power source for traveling such as an internal combustion engine. The braking device 7 can individually adjust the braking force generated on each wheel 3 of the vehicle 2. The braking device 7 is a variety of hydraulic braking devices in which a hydraulic fluid connected from a master cylinder 9 to a wheel cylinder 11 via a VSC (Vehicle Stability Control) actuator 10 is filled with a brake fluid as a working fluid. In the braking device 7, the hydraulic braking unit 12 operates according to the braking pressure supplied to the wheel cylinder 11 to generate a pressure braking force on the wheel 3.

  The ECU 8 controls driving of each part of the vehicle 2 and includes an electronic circuit mainly composed of a known microcomputer including a CPU, a ROM, a RAM, and an interface. The ECU 8 is electrically connected to various sensors and detection devices attached to various parts of the vehicle 2 such as a master cylinder pressure sensor 13 for detecting the master cylinder pressure, and each wheel speed sensor 14 for detecting the rotational speed of each wheel 3. And an electrical signal corresponding to the detection result is input. The ECU 8 drives each part of the vehicle 2 such as the power source 5 and the VSC actuator 10 of the braking device 7 by executing a stored control program based on various input signals and various maps input from various sensors. A signal is output to control these driving operations. The ECU 8 controls the VSC actuator 10 according to the traveling state of the vehicle 2, individually increases / decreases the wheel cylinder pressure of the wheel cylinder 11 provided on each wheel 3, and individually controls the braking force on each wheel 3. Thus, it is possible to realize a braking force control function such as ABS (Antilock Bracket System) control.

  Here, the braking device 7 will be described in more detail. As described above, the braking device 7 includes the master cylinder 9, the VSC actuator 10, the wheel cylinder 11, the hydraulic braking unit 12, and the like. The master cylinder 9 applies a master cylinder pressure as an operation pressure to the brake fluid (working fluid) according to a pedal depression force (operation force) input to the brake pedal 6 as a braking operation member. Here, the master cylinder 9 applies the master cylinder pressure according to the pedal depression force increased at a predetermined boost ratio by the booster 16 as a booster. The wheel cylinder 11 generates a braking force generated on the wheel 3 of the vehicle 2 when a wheel cylinder pressure as a braking pressure based on the master cylinder pressure acts. The wheel cylinder pressure has a value corresponding to the magnitude of the braking force generated by the hydraulic braking unit 12 of each wheel 3. The VSC actuator 10 can individually adjust the braking force generated in each wheel 3 by individually adjusting the wheel cylinder pressure supplied to the wheel cylinder 11. The hydraulic braking unit 12 includes a caliper, a brake pad, a disc rotor, and the like.

  In the braking device 7, the master cylinder pressure is applied to the brake fluid by the master cylinder 9 according to the pedal depression force acting on the brake pedal 6 basically when the driver operates the brake pedal 6. In the braking device 7, the hydraulic braking unit 12 is operated by the pressure corresponding to the master cylinder pressure acting as the wheel cylinder pressure in each wheel cylinder 11. Each hydraulic braking unit 12 has a predetermined rotational resistance force according to the wheel cylinder pressure acting on the disk rotor rotating together with the wheel 3 by the brake pad being in contact with and pressed against the disk rotor by the wheel cylinder pressure. A braking force can be applied to the disk rotor and the wheel 3 rotating integrally therewith. During this time, in the braking device 7, the wheel cylinder pressure is appropriately adjusted by the VSC actuator 10 according to the operating state.

  Here, the VSC actuator 10 individually adjusts the braking force generated in each wheel 3 by individually increasing, reducing, and maintaining the wheel cylinder pressure independently of the four wheels. The VSC actuator 10 is provided on the hydraulic path of the brake fluid that connects the master cylinder 9 and the wheel cylinder 11, and increases or decreases the hydraulic pressure in each wheel cylinder 11 by control by the ECU 8 separately from the brake operation of the brake pedal 6. The braking force applied to each wheel 3 is controlled. The VSC actuator 10 is configured by various hydraulic control devices (hydraulic control circuits) controlled by the ECU 8, for example. The VSC actuator 10 includes, for example, a plurality of pipes, an oil reservoir, an oil pump, each hydraulic pipe connected to each wheel cylinder 11 provided in each wheel 3, and the hydraulic pressure of each hydraulic pipe is increased, reduced, and held respectively. A plurality of solenoid valves for performing the operation. The VSC actuator 10 functions as a working fluid pressure adjusting unit that transmits the hydraulic pressure (master cylinder pressure) in the hydraulic piping as it is, or pressurizes and depressurizes it to each wheel cylinder 11 described later in accordance with a control command of the ECU 8.

  The VSC actuator 10 is, for example, a wheel cylinder that acts on the wheel cylinder 11 according to the amount of operation (depression amount) of the brake pedal 6 by the driver by driving an oil pump or a predetermined electromagnetic valve according to a control command of the ECU 8. The pressure can be regulated. Further, when executing various braking force control such as ABS control, the VSC actuator 10 acts on the wheel cylinder 11 by driving an oil pump or a predetermined electromagnetic valve according to a control command of the ECU 8, for example. It can be operated in a pressure-increasing mode for increasing the wheel cylinder pressure, a holding mode for maintaining the pressure almost constant, a pressure-reducing mode for reducing the pressure. The VSC actuator 10 can set the mode individually for each wheel cylinder 11 of each wheel 3 according to the traveling state of the vehicle 2 under the control of the ECU 8. That is, the VSC actuator 10 can individually adjust the braking force acting on each wheel 3 according to the traveling state of the vehicle 2 regardless of the operation of the brake pedal 6 by the driver.

  An example of the VSC actuator 10 is shown in FIG. In the following description, the subscript FL indicates the left front wheel 3FL, FR indicates the right front wheel 3FR, RL indicates the left rear wheel 3RL, and RR indicates the component related to the right rear wheel 3RR. Further, when it is not necessary to particularly separate the left front wheel 3FL, the right front wheel 3FR, the left rear wheel 3RL, and the right rear wheel 3RR, it is necessary to distinguish the four wheels in the other configurations as well, just like the wheel 3. If not, the subscripts FL, FR, RL, RR are omitted. The configuration of the VSC actuator 10 is not limited to the configuration illustrated in FIG.

  The VSC actuator 10 is connected to the wheel cylinders 11FL, 11FR, 11RL, and 11RR of the hydraulic brake portions 12FL, 12FR, 12RL, and 12RR by brake fluid pipes 42FL, 42FR, 42RL, and 42RR. The VSC actuator 10 and the master cylinder 9 are connected by a first brake fluid pipe 45A and a second brake fluid pipe 45B. The brake fluid is filled in the master cylinder 9, the brake fluid piping 42FL, 42FR, 42RL, 42RR, the first brake fluid piping 45A, the second brake fluid piping 45B, and the brake fluid passage provided in the VSC actuator 10.

  The VSC actuator 10 includes a first hydraulic pressure transmission system 51A that transmits the brake hydraulic pressure from the master cylinder 9 to the wheel cylinders 11FR and 11RL of the hydraulic brake units 12FR and 12RL, and the wheels of the hydraulic brake units 12FL and 12RR. And a second hydraulic pressure transmission system 51B that transmits to the cylinders 11FL and 11RR. The first hydraulic pressure transmission system 51A is connected to the master cylinder 9 by a first brake fluid pipe 45A, and the second hydraulic pressure transmission system 51B is connected to the master cylinder 9 by a second brake fluid pipe 45B.

  In the first hydraulic pressure transmission system 51A, the brake hydraulic pressure from the master cylinder 9 includes the first brake fluid piping 45A, the first master cut valve 52A that is a flow control valve, and the first high-pressure brake fluid piping 58A that is a brake fluid passage. This is transmitted to the wheel cylinders 11FR and 11RL via the holding valves 53FR and 53RL and the brake fluid pipes 42FR and 42RL. In the first hydraulic pressure transmission system 51A, pressure reducing valves 54FR and 54RL are connected between the holding valves 53FR and 53RL and the wheel cylinders 11FR and 11RL. Here, the first master cut valve 52A and the holding valves 53FR, 53RL are normally open solenoid valves (NO valves) that are open when not energized, and the pressure reducing valves 54FR, 54RL are not energized. This is a normally closed solenoid valve (NC valve) in a closed state. The holding valves 53FR and 53RL are sometimes called pressure-increasing valves.

  In the first hydraulic pressure transmission system 51A, by operating the holding valves 53FR and 53RL and the pressure reducing valves 54FR and 54RL, the wheel cylinder pressure acting on the wheel cylinders 11FR and 11RL is increased and decreased, and the right front wheel 3FR and The braking force of the left rear wheel 3RL is adjusted. In the first hydraulic pressure transmission system 51A, for example, by changing the duty ratio between the opening time and the closing time of the holding valves 53FR and 53RL and the pressure reducing valves 54FR and 54RL, the wheel acting on the wheel cylinders 11FR and 11RL. Increase or decrease the cylinder pressure.

  In the second hydraulic pressure transmission system 51B, the brake fluid pressure from the master cylinder 9 is the second brake fluid pipe 45B, the second master cut valve 52B that is a flow control valve, and the second high-pressure brake fluid pipe 58B that is a brake fluid passage. , Are transmitted to the wheel cylinders 11FL and 11RR via the holding valves 53FL and 53RR and the brake fluid pipes 42FL and 42RR. In the second hydraulic pressure transmission system 51B, pressure reducing valves 54FL and 54RR are connected between the holding valves 53FL and 53RR and the wheel cylinders 11FL and 11RR. Here, the second master cut valve 52B and the holding valves 53FL and 53RR are normally open solenoid valves (NO valves) that are open when the power is not supplied, and the pressure reducing valves 54FL and 54RR are the valves when the power is not supplied. This is a normally closed solenoid valve (NC valve) in a closed state. The holding valves 53FR and 53RL are sometimes called pressure-increasing valves.

  In the second hydraulic pressure transmission system 51B, by operating the holding valves 53FL and 53RR and the pressure reducing valves 54FL and 54RR, the wheel cylinder pressure acting on the wheel cylinders 11FL and 11RR is increased or decreased, and the left front wheel 3FL and the right The braking force of the rear wheel 3RR is adjusted. In the second hydraulic pressure transmission system 51B, for example, the wheel cylinder pressure acting on each wheel cylinder 11FL, 11RR is changed by changing the duty ratio between the opening time and the closing time of the holding valves 53FL, 53RR and the pressure reducing valves 54FL, 54RR. Increase or decrease.

  The first master cut valve 52A and the second master cut valve 52B (hereinafter may be referred to as “master cut valve 52” as needed), which are flow control valves, include a linear solenoid and a spring. Have. The master cut valve 52 adjusts the opening to create a differential pressure (master cut valve differential pressure) ΔP_SMC (= Pe−Pi) between the brake fluid pressure Pe at the outlet and the brake fluid pressure Pi at the inlet. The differential pressure ΔP_SMC can be changed linearly.

  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 13 and acquired by the ECU 8. 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. And is acquired by the ECU 8. The master cut valve differential pressure can also be obtained from the control current supplied to the master cut valve 52.

  The outlets of the pressure reducing valves 54FR and 54RL and the first brake fluid piping 45A are connected to the first brake fluid reservoir 57A, respectively. Further, the outlets of the pressure reducing valves 54FL and 54RR and the second brake fluid pipe 45B are connected to the second brake fluid reservoir 57B, respectively.

  The VSC actuator 10 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. In the VSC actuator 10, when the first pump 56A pressurizes the brake fluid in the first hydraulic pressure transmission system 51A, the wheel cylinder pressure applied to the wheel cylinders 11FR and 11RL increases. Similarly, in the VSC actuator 10, when the second pump 56B pressurizes the brake fluid in the second hydraulic pressure transmission system 51B, the wheel cylinder pressure applied to the wheel cylinders 11FL and 11RR increases.

  The first pump 56A and the second pump 56B are driven by a pump driving motor 55. The ECU 8 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.

  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 and the first brake fluid reservoir 57A. Circulates between the second brake fluid reservoir 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 wheel cylinder pressure acting on each wheel cylinder 11FR, 11RL, 11FL, 11RR can be increased more than the brake fluid pressure in the master cylinder 9.

  Further, the VSC actuator 10 reduces the opening degree of the first master cut valve 52A and the second master cut valve 52B even when the first pump 56A and the second pump 56B are not operating. Thus, the wheel cylinder pressure acting on each wheel cylinder 11FR, 11RL, 11FL, 11RR can be held. Even if the brake fluid pressure (master cylinder pressure) in the master cylinder 9 decreases, the master cut valve differential pressure is reduced by reducing the opening of the master cut valve 52 in accordance with the change in the brake fluid pressure in the master cylinder 9. And the wheel cylinder pressure acting on each wheel cylinder 11FR, 11RL, 11FL, 11RR can be maintained.

  The ECU 8 controls the operation of the VSC actuator 10 to generate a target wheel braking force that is a target wheel braking force of each wheel 3. The ECU 8 determines the target wheel braking force of each wheel 3 based on the target vehicle braking force. Here, the target vehicle braking force is, for example, a target value required for braking the vehicle 2 according to the operation state amount of the brake pedal 6 by the driver. The operation state amount of the brake pedal 6 is, 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 each wheel 3 in order to apply the target vehicle braking force to the vehicle 2.

  When the actual wheel braking force is insufficient with respect to the target wheel braking force, the ECU 8 increases the wheel cylinder pressure supplied to the wheel cylinder 11 of the wheel 3. In this pressure increasing mode, the holding valve 53 corresponding to the wheel 3 is opened, and the pressure reducing valve 54 is closed. At this time, the pressure increasing speed can be controlled by duty control of the holding valve 53. Further, the ECU 8 can drive the pump 56 when the master cylinder pressure is insufficient to generate the target wheel braking force.

  On the other hand, when the actual wheel braking force exceeds the target wheel braking force, the ECU 8 reduces the wheel cylinder pressure supplied to the wheel cylinder 11 of the wheel 3. In this decompression mode, the holding valve 53 corresponding to the wheel 3 is closed and the decompression valve 54 is opened. Further, the VSC actuator 10 can hold the wheel cylinder pressure supplied to the wheel cylinder 11 of each wheel 3. In this holding mode, the ECU 8 closes the holding valve 53 and the pressure reducing valve 54 corresponding to the wheel 3 to be held.

  In the braking device 7 configured as described above, when the driver operates the brake pedal 6 and a pedal depression force is input to the brake pedal 6, the pedal depression force is doubled by the booster 16 at a predetermined boost ratio. It is transmitted to the master cylinder 9. The pedal depression force increased by the booster 16 and transmitted to the master cylinder 9 is converted into the master cylinder pressure in the master cylinder 9 and transmitted to the wheel cylinder 11 via the VSC actuator 10. At this time, the wheel cylinder pressure supplied to the wheel cylinder 11 is adjusted to a predetermined hydraulic pressure by the VSC actuator 10 and transmitted to the wheel cylinder 11. Each hydraulic braking unit 12 rotates the wheel 3 by applying a pressure braking torque by a frictional force by applying a predetermined wheel cylinder pressure to each wheel cylinder 11 and pressing a brake pad of the caliper against the disc rotor. You can slow down.

  Then, the ECU 8 of this embodiment controls the VSC actuator 10 according to the traveling state of the vehicle 2 and individually increases or decreases the wheel cylinder pressures of the wheel cylinders 11 provided on the wheels 3, respectively. The ABS function and the like of the vehicle 2 can be realized by individually controlling the power. That is, the ECU 8 can execute, for example, ABS control for controlling the braking device 7 to control the slip state of the wheel 3 as control for stabilizing the behavior of the vehicle 2.

  As the ABS control, the ECU 8 adjusts the braking force of the wheel 3 in the slip state when the wheel 3 slips, for example, when the driver depresses the brake pedal 6 (braking operation). The optimum braking force according to the traveling state is applied to the wheel 3. In the ABS control, the ECU 8 controls the slip state of the wheel 3, for example, the slip rate of the wheel 3 by adjusting the wheel cylinder pressure of the braking device 7 and controlling the braking force generated on the wheel 3.

Here, the slip ratio of each wheel 3 is an index representing slip (slip) between the tire of the wheel 3 and the road surface. The ECU 8 can calculate using various methods based on, for example, the rotation speed (wheel speed) of each wheel 3 detected by each wheel speed sensor 14. For example, the ECU 8 uses the following formula (1) based on the wheel speed Vw of each wheel 3 detected by each wheel speed sensor 14 and the vehicle speed Vr of the vehicle 2 estimated from the wheel speed Vw of each wheel 3. Thus, the slip ratio S can be obtained. The slip ratio S is calculated corresponding to each wheel 3 based on each detected value by each wheel speed sensor 14. The vehicle speed may be detected by a vehicle speed sensor provided separately from each wheel speed sensor 14.

S = (Vr−Vw) / Vr (1)

  The ECU 8 basically controls the braking force generated on the wheels 3 so that the actual slip ratio becomes the target slip ratio. Here, the target slip ratio is, for example, a target slip ratio in the vicinity of the peak μ slip ratio at which the friction coefficient of the tire of the wheel 3 is maximum. The target slip ratio may have a predetermined range.

  The ECU 8 executes ABS control in order to suppress slip that may occur between the wheels 3 and the road surface when the braking device 7 is activated in response to the driver's depressing operation of the brake pedal 6 while the vehicle 2 is traveling. To do. For example, the ECU 8 starts the ABS control when the slip rate of the wheel 3 exceeds a preset ABS control start threshold. The ABS control start threshold is set in advance according to the slip state of the wheel 3, the braking distance of the vehicle 2, the behavioral stability, the steering performance, and the like based on the actual vehicle evaluation and the like, and is stored in the storage unit of the ECU 8. In this case, the ECU 8 controls the braking force generated on the wheel 3 by adjusting the wheel cylinder pressure of the braking device 7 so that the actual slip ratio becomes the target slip ratio. For example, the ECU 8 calculates an ABS control amount (ABS slip suppression control amount) based on the deviation between the actual slip rate and the target slip rate, and controls the VSC actuator 10 of the braking device 7 based on the ABS control amount. Then, the wheel cylinder pressure is adjusted to control the braking force generated on the wheel 3. Here, the ABS control amount is a control amount for controlling the VSC actuator 10 in the ABS control, and is a control amount capable of realizing the target slip ratio. The ECU 8 reduces the wheel cylinder pressure to reduce the braking force when the actual slip ratio becomes larger than the target slip ratio, while reducing the wheel cylinder pressure when the actual slip ratio becomes smaller than the target slip ratio. Increase the braking force by increasing the pressure. Typically, the ECU 8 can shorten the braking distance of the vehicle 2 while preventing the brake lock by repeating this periodically, and can improve the behavioral stability and steering performance of the vehicle 2.

  The ECU 8 of the present embodiment can execute linear pulse pressure increase control during the ABS operation in which the slip state of the wheel 3 is controlled by controlling the VSC actuator 10 to adjust the wheel cylinder pressure. Here, the linear pulse pressure increase control means that the wheel cylinder pressure is controlled by controlling the linear valve of the VSC actuator 10 during the ABS operation and when the wheel cylinder pressure is increased, and the wheel cylinder pressure is increased and maintained. This is control to increase the pressure.

  In the present embodiment, the linear valve to be controlled in the linear pulse pressure increase control may be described as the holding valve 53FR, 53RL, 53FL, 53RR (hereinafter referred to as “holding valve 53” as necessary) of the VSC actuator 10. )). The holding valve 53 of this embodiment has a linear solenoid and a spring. The holding valve 53 is a normally open linear 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.

  Here, such a braking force control device 1 has a holding valve 53 in the region where the pressure difference between the master cylinder pressure and the wheel cylinder pressure of the target wheel 3 is large when pressure is increased during ABS operation. When the flow rate of the brake fluid suddenly increases due to, etc., there is a possibility that valve vibration may occur in the holding valve 53 or the like. In this case, the braking force control apparatus 1 may generate oil column resonance noise (so-called “cool noise”) from the hydraulic pulsation of the piping. Such a phenomenon tends to occur when, for example, the ABS operates when sudden braking is performed while the vehicle 2 is traveling on a low μ road (for example, a snowy road or a frozen road).

  On the other hand, the ECU 8 periodically increases and holds the wheel cylinder pressure of the wheel 3 to be increased by controlling the holding valve 53 under a predetermined condition when the pressure is increased during the ABS operation. The linear pulse pressure increase control for increasing the wheel cylinder pressure is executed repeatedly. Thereby, the braking force control apparatus 1 can suppress generation | occurrence | production of an oil column resonance sound, and can suppress generation | occurrence | production of unusual noise by performing linear pulse pressure increase control during the pressure increase at the time of ABS action | operation.

  FIG. 3 is a diagram for explaining an example of linear pulse pressure increase control, in which the horizontal axis is a time axis and the vertical axis is a hydraulic pressure. In FIG. 3, a dotted line L1 represents a normal target pressure (target pressure when linear pulse pressure increase control is not performed) L1 of the wheel cylinder pressure at the time of ABS operation pressure increase. A solid line L2 represents the control pressure L2 of the wheel cylinder pressure in the linear pressure increase control at the time of ABS operation pressure increase. A solid line L3 represents the control pressure L3 of the wheel cylinder pressure in the linear pulse pressure increase control at the time of ABS operation pressure increase. As will be described later, the ECU 8 can execute normal linear pressure increase control when the pressure increase during the ABS operation is not executed when the linear pulse pressure increase control is not executed. The linear pressure-increasing control refers to controlling the linear valve of the VSC actuator 10 during ABS operation and increasing the wheel cylinder pressure, thereby increasing the wheel cylinder pressure to a substantially constant pressure increase gradient (amount of pressure increase per unit time). ).

  Here, for example, as described above, the ECU 8 determines the target pressure at the time of pressure increase during the ABS operation according to the ABS control amount calculated based on the deviation between the actual slip ratio and the target slip ratio. L1 can be set. That is, when the actual slip ratio becomes smaller than the target slip ratio, the ECU 8 converges the actual slip ratio to the target slip ratio based on the deviation between the actual slip ratio and the target slip ratio. As described above, the target pressure L1 of the wheel cylinder pressure of the wheel 3 that is the target at the time of the ABS operation pressure increase is set with a constant gradient.

  The ECU 8 controls the holding valve 53 in the linear pressure increase control during the ABS operation pressure increase so that the control pressure L2 of the wheel cylinder pressure of the target wheel 3 follows the target pressure L1. The cylinder pressure is increased with a substantially constant pressure increase gradient.

  On the other hand, in the linear pulse pressure increase control during the ABS operation pressure increase, the ECU 8 controls the holding valve 53 to repeat the pressure increase and hold, so that the wheel cylinder of the target wheel 3 with respect to the target pressure L1. The pressure control pressure L3 is increased stepwise. Here, the holding time of the wheel cylinder pressure in the linear pulse pressure increase control may be set in advance according to the mechanical characteristics, specifications, performance, etc. of the holding valve 53, for example, the minimum time during which the oil pressure can be reliably held. Is set. Similarly, the pressure increase cycle of the wheel cylinder pressure in the linear pulse pressure increase control may be set in advance as a fixed cycle. The ECU 8 sets a pressure increase gradient at each pressure increase in the linear pulse pressure increase control based on the target pressure L1 set as described above and a holding time and a pressure increase period that are fixedly set in advance. At this time, for example, the ECU 8 sets a pressure increase gradient at each pressure increase so that the control pressure L3 at the end of the holding time is located above the target pressure L1, and the wheel cylinder pressure of the target wheel 3 is set. The control pressure L3 is controlled.

  By the way, the braking force control apparatus 1 periodically increases and holds the wheel cylinder pressure of the target wheel 3 by controlling the holding valve 53 as illustrated in FIG. 4 in the linear pulse pressure increasing control. Since it is repeated, for example, when the pressure increase control of the ABS control is interrupted for various reasons, the target pressure L1 and the actual control pressure L3 are determined depending on the timing of interruption (for example, time t1 in FIG. 4). There is a risk that the divergence of will increase. That is, in the braking force control apparatus 1, for example, in a region where the pressure increase gradient at the time of ABS operation pressure increase is relatively high, the difference between the target pressure L1 at the end of the control and the actual control pressure L3 becomes large. Therefore, the controllability is deteriorated, that is, there is a risk of overshoot.

  Therefore, the braking force control apparatus 1 of the present embodiment sets conditions for executing the linear pulse pressure increase control, executes the linear pulse pressure increase control when the predetermined condition is satisfied, and executes the predetermined condition. If this condition is not satisfied, the linear pulse pressure increase control is not executed. Thereby, the braking force control apparatus 1 is aiming at coexistence with suppression of abnormal noise, and suppression of controllability deterioration.

  Specifically, the ECU 8 is based on a target differential pressure between the master cylinder pressure and the wheel cylinder pressure during ABS operation (hereinafter sometimes referred to as “target differential pressure”) and a target wheel cylinder pressure. Determine whether to perform linear pulse pressure increase control. The target wheel cylinder pressure is calculated based on the target pressure L1 of the wheel cylinder pressure at the time of ABS operation pressure increase set as described above. The target differential pressure at the time of ABS operation increase is detected by the target wheel cylinder pressure on the target pressure L1 of the wheel cylinder pressure at the time of ABS operation increase and the master cylinder pressure sensor 13 set as described above. It is calculated by calculating the difference from the actual master cylinder pressure.

  Specifically, the ECU 8 determines that the target differential pressure between the master cylinder pressure and the wheel cylinder pressure when the ABS operation pressure is increased is larger than a preset control permission differential pressure, and the target wheel cylinder pressure when the ABS operation pressure is increased. When the amount of change (the amount of change per predetermined time), for example, the difference between the current value and the previous value is within a preset control permission range, linear pulse pressure increase control is executed. The ECU 8 determines whether or not the target differential pressure between the master cylinder pressure and the wheel cylinder pressure during the ABS operation pressure increase is equal to or lower than the control permission differential pressure, or the current value of the target wheel cylinder pressure during the ABS operation pressure increase. When the difference from the previous value is outside the control permission range, the linear pulse pressure increase control is not executed. In this case, the ECU 8 executes normal linear pressure increase control instead of the linear pulse pressure increase control. Here, the amount of change in the target wheel cylinder pressure is described as using the difference between the current value of the target wheel cylinder pressure and the previous value, but the present invention is not limited to this. For example, the difference between the current value and the previous value May be used.

  The ECU 8 calculates the target wheel cylinder pressure in the current control cycle based on the target pressure L1 of the wheel cylinder pressure at the time of ABS operation pressure increase. Then, the ECU 8 calculates the difference between the target wheel cylinder pressure in the current control cycle and the master cylinder pressure in the current cycle detected by the master cylinder pressure sensor 13, so that the master cylinder during the ABS operation pressure increase is calculated. The target differential pressure between the pressure and the wheel cylinder pressure is calculated. Then, the ECU 8 compares the target differential pressure with a preset control permission differential pressure, and determines whether the target differential pressure is greater than the control permission differential pressure. Here, the control permission differential pressure is a difference in magnitude that may cause noise due to an increase in the flow rate of the brake fluid in the VSC actuator 10 when the differential pressure between the master cylinder pressure and the wheel cylinder pressure is adjusted. It is set in advance based on actual vehicle evaluation according to the pressure, and stored in the storage unit of the ECU 8. In other words, the control-permitted differential pressure is generated when the pressure difference between the master cylinder pressure and the wheel cylinder pressure is adjusted, the flow rate of the brake fluid increases too rapidly at the holding valve 53, etc., causing valve vibration, and oil column resonance from the hydraulic pulsation of the piping. It is set in accordance with a differential pressure having a magnitude that may cause abnormal noise such as sound. The control permission differential pressure is set to about 10 MPa, for example.

  When the target differential pressure at the time of ABS operation pressure increase is larger than this control permission differential pressure, that is, the target differential pressure is increased when the flow rate of the brake fluid rapidly increases at the holding valve 53 or the like when the differential pressure is adjusted. When the pressure is a differential pressure that may cause vibration of the oil column due to the hydraulic pulsation of the pipe, linear pulse pressure increase control is permitted. On the other hand, when the target differential pressure during the ABS operation pressure increase is equal to or less than the control permission differential pressure, the ECU 8 causes the brake fluid flow rate to rapidly increase at the holding valve 53 or the like when the differential pressure is adjusted. If the differential pressure is such that there is no possibility that the oil column resonance noise is generated from the hydraulic pulsation of the pipe due to the valve vibration, the linear pressure increase control is performed instead of the linear pulse pressure increase control.

  Further, for example, the ECU 8 sets the target wheel cylinder pressure in the current control cycle based on the target pressure L1 of the wheel cylinder pressure at the time of ABS operation increase as the current value of the target wheel cylinder pressure at the time of ABS operation increase, The target wheel cylinder pressure in the previous control cycle is set as the previous value of the target wheel cylinder pressure at the time of ABS operation pressure increase. Then, the ECU 8 calculates the difference between the current value and the previous value of the target wheel cylinder pressure at the time of ABS operation pressure increase. The difference between the current value and the previous value of the target wheel cylinder pressure at the time of ABS operation pressure increase corresponds to the target pressure increase gradient of the wheel cylinder pressure at the time of ABS operation pressure increase. The larger the difference between the current value and the previous value, the greater the pressure increase gradient. The ECU 8 compares the difference between the current value and the previous value of the target wheel cylinder pressure during the ABS operation pressure increase and a preset control permission range, and the difference between the current value and the previous value is within the control permission range. It is determined whether or not. Here, the control permission range is set in advance based on actual vehicle evaluation or the like with respect to the difference between the current value and the previous value of the target wheel cylinder pressure during the ABS operation pressure increase, and is stored in the storage unit of the ECU 8. . The control permission range is, for example, a range between a preset difference upper limit value (upper limit) and a difference lower limit value (lower limit). In the control permission range, a difference lower limit value is set according to a pressure increase gradient that may cause abnormal noise due to an increase in the flow rate of the brake fluid in the VSC actuator 10 when the wheel cylinder pressure is increased, and the control ends. The upper limit value of the difference is set according to the pressure increase gradient that may possibly deteriorate the pressure adjustment accuracy of the wheel cylinder pressure. That is, the lower limit of the difference is that when the wheel cylinder pressure is increased, the flow rate of the brake fluid suddenly increases at the holding valve 53 and the valve vibration is generated, and abnormal noise such as oil column resonance noise is generated from the hydraulic pulsation of the piping. It is set according to the pressure-increasing gradient or the like that may be present. On the other hand, as described above, the upper limit of the difference is a pressure increasing gradient that may cause a relatively large difference between the target wheel cylinder pressure at the end of the control and the actual wheel cylinder pressure. It is set according to a pressure increasing gradient or the like that may deteriorate the controllability due to the difference between the target wheel cylinder pressure at the end and the actual wheel cylinder pressure. The difference lower limit value (change amount lower limit value) of the control permission range is set to, for example, about 10 MPa / sec. The difference upper limit value (change amount upper limit) is set based on, for example, the linear pulse pressure increase / hold duty ratio, the linear pulse pressure increase / hold cycle, the allowable overshoot amount, and the like. The allowable overshoot amount is a hydraulic overshoot amount that is allowable in consideration of ensuring controllability and the like, and is arbitrarily set in advance. The difference upper limit value can be calculated by, for example, [difference upper limit value = allowable overshoot amount / linear pulse pressure increase / hold cycle × linear pulse pressure increase / hold duty ratio]. For example, when the linear pulse pressure increase / hold duty ratio is 50%, the linear pulse pressure increase / hold cycle is 0.02 sec, and the allowable overshoot amount is 1.0 MPa, the difference upper limit value is the difference upper limit value. = 1.0 / 0.02 × 50/100 = about 25 MPa / sec.

  When the difference between the current value and the previous value of the target wheel cylinder pressure at the time of the ABS operation pressure increase is within the control permission range, the ECU 8 is larger than the difference lower limit value and smaller than the difference upper limit value. The linear pulse pressure increase control is allowed. As a result, the ECU 8 is in a case where the flow rate of the brake fluid excessively increases in the holding valve 53 and the like, and the valve vibration is generated, and there is a possibility that the oil column resonance noise is generated from the hydraulic pulsation of the pipe. The linear pulse pressure increase control can be allowed when there is no risk of deterioration in controllability due to the difference between the target wheel cylinder pressure and the actual wheel cylinder pressure. On the other hand, when the difference between the current value and the previous value of the target wheel cylinder pressure at the time of ABS operation pressure increase is outside the control permission range, the ECU 8 is, in other words, when the difference is equal to or less than the difference lower limit value, or When the difference is greater than or equal to the difference upper limit value, linear pressure increase control is performed instead of linear pulse pressure increase control. As a result, the ECU 8 causes the brake fluid flow rate to suddenly increase at the holding valve 53 and the like, causing no valve vibration, and there is no risk of oil column resonance from the hydraulic pulsation of the pipe, or the target at the end of control. When there is a possibility that the controllability is deteriorated due to the difference between the wheel cylinder pressure and the actual wheel cylinder pressure, the linear pulse pressure increase control can be prevented from being executed.

  Next, an example of control by the ECU 8 will be described with reference to the flowchart of FIG. Note that these control routines are repeatedly executed at a control cycle of several ms to several tens of ms.

First, the ECU 8 determines whether or not the linear pulse pressure increase request determination is established (step ST1). Here, the ECU 8 determines whether or not the linear pulse pressure increase request determination is satisfied by determining whether or not all of the following condition 1, condition 2, and condition 3 are satisfied.
(Condition 1) The linear pulse pressure increase permission request is ON.
(Condition 2) [Target differential pressure between master cylinder pressure and wheel cylinder pressure> Control permission differential pressure ΔPstart] is satisfied.
(Condition 3) [Difference upper limit value TargetPmax> Current value of target wheel cylinder pressure-Previous value of target wheel cylinder pressure> Difference lower limit value TargetPmin].

  Condition 1 is that the ECU 8 calculates a target pressure of the wheel cylinder pressure based on the deviation between the actual slip ratio and the target slip ratio, and there is a request for a large ABS operation pressure increase gradient according to the target pressure of the wheel cylinder pressure. In some cases, the linear pulse pressure increase permission request is turned ON. As described above, the condition 2 is that the target differential pressure between the master cylinder pressure and the wheel cylinder pressure when the ABS operation is increased is caused by the increase in the flow rate of the brake fluid in the VSC actuator 10 when the differential pressure is adjusted. Thus, it is determined whether or not the control permission differential pressure ΔPstart is larger than the magnitude that may cause abnormal noise. Here, the ECU 8 may calculate the target differential pressure by the method described above. Condition 3 is to determine whether or not the difference between the current value and the previous value of the target wheel cylinder pressure during the ABS operation pressure increase is within the control permission range, as described above. Here, the control permission range is a range from the difference lower limit value TargetPmin to the difference upper limit value TargetPmax. The difference lower limit value TargetPmin is set according to a pressure increase gradient that may cause abnormal noise due to an increase in the flow rate of the brake fluid in the VSC actuator 10 when the wheel cylinder pressure is increased. The difference upper limit value TargetPmax is set according to a pressure increasing gradient that may cause a large difference between the target wheel cylinder pressure at the end of the control and the actual wheel cylinder pressure, thereby deteriorating controllability. Further, the ECU 8 may calculate the difference by the method described above.

  When it is determined in step ST1 that all of the above conditions 1, 2 and 3 are satisfied and the linear pulse pressure increase request determination is satisfied (step ST1: Yes), the ECU 8 sets a linear pulse pressure increase request flag. Turn on (step ST2).

  Next, as the linear pulse pressure increase correction calculation, the ECU 8 controls the holding valve 53 to increase and hold the target pressure of the wheel cylinder pressure based on the deviation between the actual slip rate and the target slip rate. By repeating the above, the target pressure is corrected so that the control pressure of the wheel cylinder pressure of the target wheel 3 is increased stepwise (step ST3). For example, the ECU 8 sets the target pressure of the wheel cylinder pressure that is set based on the deviation between the actual slip ratio and the target slip ratio, the holding time and the pressure increase period in the linear pulse pressure increase control that is fixedly set in advance. Based on the above, a pressure increase gradient at each pressure increase in the linear pulse pressure increase control is set, and the target pressure is corrected.

  The ECU 8 controls the holding valve 53 of the wheel 3 that is the target of pressure increase during the ABS operation based on the target pressure of the wheel cylinder pressure in the linear pulse pressure increase control corrected in step ST3, and performs linear pulse pressure increase control. (Step ST4), the current control cycle is terminated, and the next control cycle is started.

  The ECU 8 determines in step ST1 that one or more of the above condition 1, condition 2, or condition 3 is not satisfied and the linear pulse pressure increase request determination is not satisfied (step ST1: No), the linear pulse pressure increase request flag is turned OFF (step ST5).

  Next, the ECU 8 controls the holding valve 53 of the wheel 3 that is subject to pressure increase during the ABS operation based on the target pressure of the wheel cylinder pressure based on the deviation between the actual slip ratio and the target slip ratio. Then, the linear pressure increasing control is executed (step ST6), the current control cycle is terminated, and the next control cycle is started.

  The braking force control apparatus 1 configured as described above is based on the linear pulse pressure increase control based on the target differential pressure between the master cylinder pressure and the wheel cylinder pressure when the ECU 8 operates the ABS and the target wheel cylinder pressure. Decide whether or not to execute. Thereby, the braking force control device 1 is used when the flow rate of the brake fluid suddenly increases at the holding valve 53 or the like, causing valve vibration, and oil column resonance noise may be generated from hydraulic pulsation of the pipe, and The linear pulse pressure increase control can be executed when the controllability is deteriorated due to the difference between the target wheel cylinder pressure at the end of the control and the actual wheel cylinder pressure, that is, there is no fear of overshoot. On the other hand, the braking force control device 1 can prevent the linear pulse pressure increase control from being executed when the oil column resonance noise is not generated or when the controllability is likely to deteriorate. . As a result, the braking force control apparatus 1 can achieve both suppression of abnormal noise and suppression of controllability deterioration.

  The braking force control device 1 according to the embodiment described above includes the braking device 7 and the ECU 8. The braking device 7 includes a master cylinder 9, a wheel cylinder 11, and a VSC actuator 10. The master cylinder 9 applies a master cylinder pressure to the brake fluid according to the pedal depression force input to the brake pedal 6. The wheel cylinder 11 generates a braking force generated on the wheel 3 of the vehicle 2 by the action of the wheel cylinder pressure based on the master cylinder pressure. The VSC actuator 10 can adjust the braking force generated in the wheel 3 by adjusting the wheel cylinder pressure supplied to the wheel cylinder 11. The ECU 8 controls the holding valve 53 of the VSC actuator 10 during the ABS operation for controlling the slip state of the wheel 3 by controlling the VSC actuator 10 and adjusting the wheel cylinder pressure to increase and hold the wheel cylinder pressure. In combination with the linear pulse pressure increase control for increasing the wheel cylinder pressure. Then, the ECU 8 determines whether or not to execute the linear pulse pressure increase control based on the target differential pressure between the master cylinder pressure and the wheel cylinder pressure during the ABS operation and the target wheel cylinder pressure. Therefore, the braking force control device 1 and the ECU 8 can both suppress the abnormal noise and suppress the deterioration of controllability, and can appropriately suppress the abnormal noise.

  The braking force control device and the control device according to the above-described embodiment of the present invention are not limited to the above-described embodiment, and various modifications can be made within the scope described in the claims.

  In the above description, the control device of the braking force control device has been described as an ECU that controls each part of the vehicle. However, the control device is not limited thereto, and is configured separately from the ECU, for example, and is detected mutually with the ECU. It may be configured to exchange information such as signals, drive signals, and control commands.

  In the above description, the ECU 8 determines whether or not the linear pulse pressure increase request determination is satisfied by determining whether or not all of the above-described conditions 1, 2 and 3 are satisfied in step ST1 of FIG. Although described as determining whether or not, for example, the determination of condition 1 may not be included.

  In the braking device 7 described above, the holding valves (pressure increasing valves) 53FR, 53RL, 53FL, 53RR and the pressure reducing valves 54FR, 54RL, 54FL, 54RR cooperate with each other to increase the pressure in the corresponding wheel cylinder 11. The pressure increasing / reducing valve is configured to hold and depressurize, but these open / close valves are replaced by one linear valve having a pressure increasing position, a holding position, and a pressure reducing position corresponding to the pressure increasing mode, holding mode, and pressure reducing mode, respectively. May be.

  The braking device 7 described above includes the first hydraulic pressure transmission system 51A in which the VSC actuator 10 is the brake hydraulic system of the right front wheel 3FR and the left rear wheel 3RL, and the brake hydraulic system of the left front wheel 3FL and the right rear wheel 3RR. However, the present invention is not limited to this. The VSC actuator 10 includes, for example, a first hydraulic pressure transmission system that is a brake hydraulic pressure system for the left front wheel 3FL and the right front wheel 3FR, and a second hydraulic pressure transmission that is a brake hydraulic pressure system for the left rear wheel 3RL and the right rear wheel 3RR. It may be constituted by a system.

DESCRIPTION OF SYMBOLS 1 Braking force control apparatus 2 Vehicle 3 Wheel 4 Accelerator pedal 5 Power source 6 Brake pedal (braking operation member)
7 Braking device 8 ECU (control device)
9 Master cylinder 10 VSC actuator (actuator)
11 Wheel cylinder 12 Hydraulic brake 52 Master cut valve 53 Holding valve (linear valve)
54 Pressure reducing valve

Claims (4)

A master cylinder that applies an operating pressure to the working fluid in accordance with an operating force input to the braking operation member, and a wheel cylinder that generates a braking force generated on a vehicle wheel when a braking pressure based on the operating pressure acts. A braking device having an actuator capable of adjusting a braking force generated in the wheel by adjusting the braking pressure supplied to the wheel cylinder;
When the ABS that controls the slip state of the wheel is controlled by controlling the actuator and adjusting the braking pressure, the linear valve of the actuator is controlled, and the braking pressure is increased and maintained in combination. And a control device capable of executing linear pulse pressure increase control for increasing pressure,
The control device determines whether or not to execute the linear pulse pressure increase control based on a target differential pressure between the operation pressure and the braking pressure during the ABS operation and a target braking pressure. It is characterized by
Braking force control device. The control device is configured to control the linear pulse pressure increase control when the target differential pressure is greater than a preset control permission differential pressure and the amount of change in the target braking pressure is within a preset control permission range. Run
When the target differential pressure is less than or equal to a preset control permission differential pressure, or when the amount of change in the target braking pressure is outside a preset control permission range, the linear pulse pressure increase control is performed. Do not run,
The braking force control apparatus according to claim 1. The control permission differential pressure is a differential pressure having such a magnitude that abnormal noise may be generated due to an increase in the flow rate of the working fluid in the actuator when the differential pressure between the operation pressure and the braking pressure is adjusted. Is set according to
The lower limit of the control permission range is set according to a pressure increase gradient that may cause abnormal noise due to an increase in the flow rate of the working fluid in the actuator when the braking pressure is increased. The upper limit is set according to the pressure increase gradient that may cause a large difference between the target braking pressure and the actual braking pressure, which may deteriorate the controllability.
The braking force control apparatus according to claim 2. A master cylinder that applies an operating pressure to the working fluid in accordance with an operating force input to the braking operation member, and a wheel cylinder that generates a braking force generated on a vehicle wheel when a braking pressure based on the operating pressure acts. A control device for a braking device having an actuator capable of adjusting a braking force generated in the wheel by adjusting the braking pressure supplied to the wheel cylinder,
When the ABS that controls the slip state of the wheel is controlled by controlling the actuator and adjusting the braking pressure, the linear valve of the actuator is controlled, and the braking pressure is increased and maintained in combination. The linear pulse pressure increase control to increase the pressure can be executed.
Whether or not to execute the linear pulse pressure increase control is determined based on a target differential pressure between the operation pressure and the braking pressure during the ABS operation and a target braking pressure. ,
Control device.

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