JP2008189100A - Brake hydraulic pressure control device - Google Patents

Abstract

The liquid loss at the initial stage of the next brake operation is reduced while performing drag reduction control.
In a brake fluid pressure control apparatus, a brake is provided in a connection path that bypasses a pump and connects to a reservoir side connection portion of a reservoir, and permits only a flow of working fluid from a discharge side to a suction side of the pump. A directional valve, and a normally closed on-off valve provided between the reservoir side connection portion of the connection path and the pump, the operation of which is controlled by a controller. It is characterized by being set higher than the output pressure of the hydraulic pressure generator when the maximum is.
[Selection] Figure 5

Description

  The present invention relates to a brake fluid pressure control device.

  In a disc brake device that generates braking force by pressing a brake pad against the braking surface of a disc rotor that rotates with the wheel, the hydraulic pressure generator brakes the hydraulic pressure according to the depression of the brake pedal operated by the vehicle driver. Transmission to the pad generates braking force.

In this disc brake device, dragging may occur in which the brake pad is in contact with the disc rotor even when the brake pedal is not depressed. If this drag occurs, it leads to a reduction in fuel consumption, so that it is required to secure a clearance between the brake pad and the disc rotor. In order to secure this clearance and prevent dragging, Patent Document 1 discloses a device for pumping back brake fluid on the wheel brake side to the master cylinder side when the brake pedal is in a non-braking state. Yes.
JP 2002-347598 A (Claim 1)

  However, since the brake fluid sucked by the pump from the wheel brake side is directly recirculated to the master cylinder in the above-described device, a fluid loss (hereinafter referred to as “fluid” hereinafter) There is a problem that the ineffective stroke of the brake pedal becomes large.

  Accordingly, an object of the present invention is to provide a brake fluid pressure control device capable of reducing the liquid loss at the initial stage of the next brake operation while performing drag reduction control.

  In order to solve the above-mentioned problem, the invention according to claim 1 includes a hydraulic pressure generating device that outputs a hydraulic pressure corresponding to a brake operation, a wheel brake, a reservoir, the wheel brake, and the hydraulic pressure generating device. A first state in which the wheel brake and the reservoir are disconnected, and a second state in which the wheel brake and the reservoir are connected and the wheel brake and the hydraulic pressure generator are disconnected. A switching valve mechanism for switching between, a pump having a suction side connected to the reservoir, and a discharge side connected to a discharge side connection provided in a hydraulic pressure path between the hydraulic pressure generating device and the switching valve mechanism, A normally open type on / off valve provided between the hydraulic pressure generating device and the discharge side connection part of the pump; and a controller for controlling the operation of the switching valve mechanism, the pump and the normally open type on / off valve. In the brake fluid pressure control device, a one-way that is provided in a connection path that bypasses the pump and connects to the reservoir-side connection portion of the reservoir, and that allows only the flow of the working fluid from the discharge side to the suction side of the pump. A valve and a normally-closed on-off valve that is controlled by the controller and is provided between the reservoir side connection portion of the connection path and the pump, and controls a valve opening pressure of the one-way valve It is characterized by being set higher than the output pressure of the hydraulic pressure generator when the maximum is.

  In this brake fluid pressure control device, the valve opening pressure of the one-way valve is set higher than the output pressure of the fluid pressure generating device when the brake operation is maximum, so that in normal brake operation, etc. The brake fluid does not flow into the reservoir through the directional valve, and the brake fluid sucked into the pump only during the drag reduction control flows into the reservoir through the one-way valve and is stored. Thereby, a clearance is secured between the brake pad of the wheel brake and the disc rotor, and dragging of the brake pad is reduced. In the next brake operation, the switching valve mechanism is set to the first state, the normally open type on-off valve is closed, the normally closed type on-off valve is opened, and the brake stored in the reservoir By returning the liquid to the wheel brake by the pump, the liquid amount corresponding to the liquid loss caused by securing the clearance can be replenished.

  According to the brake fluid pressure control device of the present invention, it is possible to reduce fluid loss at the initial stage of the next brake operation while performing drag reduction control. In addition, since only the amount of liquid sucked by the pump and stored in the reservoir is discharged from the pump, the discharge amount is not excessive or insufficient.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

FIG. 1 is a diagram showing a configuration of a brake fluid pressure control device according to an embodiment of the present invention and a state during normal brake operation.
The brake hydraulic pressure control device 1 shown in FIG. 1 includes a hydraulic pressure generating device 2, wheel brakes (left front wheel brake BR1, right rear wheel brake BR2) mounted on the wheels W1, W2, a reservoir 3, , Switching valve mechanism VF (first switching valve 41, second switching valve 51), switching valve mechanism VR (first switching valve 42, second switching valve 52), pump 6, regulator valve (normally open type on-off valve) 7 , A controller 8, a one-way valve 9, a drag reduction valve (normally closed on-off valve) 10, and a master cylinder pressure sensor MS.

  The hydraulic pressure generating device 2 includes a tandem master cylinder 2B provided with a reservoir R, a first output port 2C, and a second output port 2D. In this hydraulic pressure generating device 2, a brake operating force is input to the master cylinder 2B from a brake pedal 2A as a brake operating member. For example, the first output port 2C outputs a hydraulic pressure corresponding to the operating force of the brake pedal 2A to the left front wheel brake BR1 and the right rear wheel brake BR2. The second output port 2D outputs a hydraulic pressure corresponding to the operating force of the brake pedal 2A to a right front wheel brake (not shown) and a left rear wheel brake (not shown).

  Since the brake fluid pressure control device on the first output port 2C side and the brake fluid pressure control device on the second output port 2D side have the same configuration, the brake on the first output port 2C side will be hereinafter described. Only the portion related to the hydraulic pressure control device will be described, and the description of the portion related to the brake hydraulic pressure control device on the second output port 2D side will be omitted.

  The first output port 2C communicates with a hydraulic pressure path L. This hydraulic pressure path L is connected to the left front wheel wheel brake BR1 via a first switching valve (normally open / close valve) 41 of the switching valve mechanism VF. It is connected to the right rear wheel wheel brake BR2 via a first switching valve (normally open / close valve) 51 of the switching valve mechanism VR. The first switching valve (normally open type on / off valve) 41 of the switching valve mechanism VF and the first switching valve (normally open type on / off valve) 51 of the switching valve mechanism VR include the left front wheel brake BR1 and the right rear wheel. One-way valves 121 and 122 that permit only the flow of brake fluid from the wheel brake BR2 side to the hydraulic pressure path L are connected in parallel. The one-way valves 121 and 122 are brakes from the wheel brakes BR1 and BR2 side to the master cylinder 2B even when the first switching valves 41 and 42 are closed when the depression force from the brake pedal 2A is released. The liquid is allowed to flow. The left front wheel brake BR1 is connected via a second switching valve (normally closed on-off valve) 51 of the switching valve mechanism VF, and the right rear wheel brake BR2 is connected to the second switching valve (switching valve mechanism VR). It is connected to the pump 6 via a normally closed on-off valve) 52.

  The switching valve mechanisms VF and VR open and close the first switching valves 41 and 42 and the second switching valves 51 and 52 by the controller 8 so that the left front wheel brake BR1 and the right rear wheel brake BR2 The first state in which the pressure generator 2 is connected and the connection between the left front wheel brake BR1 and the right rear wheel brake BR2 and the reservoir 3 is disconnected, and the left front wheel brake BR1 and the right rear wheel brake It has a function of switching between the second state in which BR2 and reservoir 3 are connected.

  The first switching valves 41 and 42 are opened during normal braking operation, and the hydraulic pressure output from the hydraulic pressure generator 2 according to the operation of the brake pedal 2A is supplied to the wheel brake BR1 through the hydraulic pressure path L. , BR2. Further, the first switching valves 41 and 42 are transmitted to the wheel brakes BR1 and BR2 from the brake pedal 2A by being closed under the control of the controller 8 when the wheels W1 and W2 are likely to be locked. Shut off the hydraulic pressure.

  The second switching valves 51 and 52 are closed during normal braking operation, and are opened by control by the controller 8 when the wheels W1 and W2 are likely to be locked, whereby the brake pedal 2A. The hydraulic pressure transmitted to the wheel brakes BR1 and BR2 is released.

  The pump 6 has a suction side connected to the reservoir 3 via a drag reduction valve (normally closed type on-off valve) 10 and a one-way valve (check valve) 15, and a discharge side connected to the hydraulic pressure generator 2 and the switching valve mechanism. A discharge-side connecting portion 6 a provided in a hydraulic pressure path L between VF and VR is connected via a one-way valve 14 and a damper 13. The pump 6 is driven by an electric motor 16 and can discharge brake fluid to the hydraulic pressure path L via a one-way valve (check valve) 14 and a damper 13.

  The regulator valve (normally open / close valve) 7 is provided between the hydraulic pressure generating device 2 and the discharge side connection portion 6a of the pump 6, and is normally opened to output the hydraulic pressure from the first output port 2C. Is transmitted to the switching valve mechanisms VF and VR through the hydraulic pressure path L. The regulator valve 7 can adjust the hydraulic pressure in the hydraulic pressure path L to a desired hydraulic pressure, and is connected to the suction side of the pump 6 via a suction valve (normally closed on-off valve) 11. Yes. By opening the suction valve 11 and operating the pump 6, the output hydraulic pressure from the master cylinder 2B of the hydraulic pressure generating device 2 is increased by the pump 6 and output to the hydraulic pressure path L. Further, the regulator valve 7, the hydraulic pressure in the hydraulic pressure path L can be adjusted to a desired hydraulic pressure. The regulator valve 7 is opened during normal brake operation and anti-lock brake control (ABS control), and the output hydraulic pressure from the hydraulic pressure generator 2 is switched through the hydraulic pressure path L to the switching valve mechanisms VF, VR. And in the pressurization control of the hydraulic pressure to the wheel brakes BR1 and BR2 such as vehicle behavior control (VSA), the output hydraulic pressure from the hydraulic pressure generator 2 is blocked.

  Further, a one-way valve 9 that permits only the flow of brake fluid from the discharge side 6a of the pump 6 to the suction side 6b is provided in the connection path 17 that bypasses the pump 6 and connects to the reservoir side connection portion 3a of the reservoir 3. Is provided. Further, a drag reduction valve (normally closed on-off valve) 10 is provided between the reservoir side connection portion 3 a and the pump 6.

The master cylinder pressure sensor MS measures the hydraulic pressure in the hydraulic pressure path L as the operation amount of the brake pedal 2A, and the measurement result is transmitted to the controller 8 via the control signal line 8b.
Note that, as the operation amount of the brake pedal 2A, a sensor that measures the operation load, stroke, depression angle, etc. of the brake pedal 2A may be used instead of the master cylinder pressure sensor MS.

Controller 8, the control signal line 8b through with receiving the measurement results of the hydraulic pressure in the hydraulic pressure passage L, via a control signal line 8a, 8b, the _{8c 1, 8c 1, 8c 2} , 8c 2, 8d, switching Connected to a valve mechanism VF, VR, pump 6, regulator valve (normally open / close valve) 7 and drag reduction valve (normally open / close valve) 10 to control these operations. That is, the controller 8 determines whether or not the hydraulic pressure is output from the master cylinder 2B of the hydraulic pressure generating device 2 by depressing the brake pedal 2A, and further, the determination result and a wheel speed sensor (not shown). The operation of the switching valve mechanisms VF and VR, the pump 6, the regulator valve (normally open / close valve) 7, the drag reduction valve (normally open / close valve) 10 and the suction valve 11 is controlled based on the input from the above. Is done.

The controller 8 includes, for example, a CPU (Central Processing Unit), a ROM (Read Only Memory), a RAM (Random Access Memory), and the like, and can be realized by an ECU (Electronic Control Unit) equipped with a predetermined control program. .
The controller 8 includes a brake operation state amount calculation unit 81, an emergency brake operation determination unit 82, an antilock calculation unit 83, a brake control unit 84, and the like.

  The brake operation state quantity calculation means 81 calculates a brake operation state quantity based on an input from the master cylinder pressure sensor MS. Specifically, values such as the pressure detected by the master cylinder pressure sensor MS and the operation speed of the brake pedal 2A, which is the time change rate of the pressure, are calculated as the parameter values of the operation state quantity.

  The emergency brake operation determination means 82 determines whether or not an emergency brake operation is performed from the brake operation state quantity calculated by the brake operation state quantity calculation means 81. For example, conditions such as an operation amount and an operation speed of the brake pedal 2A Or any combination thereof. That is, the amount of brake control required by the driver can be determined from the operation amount of the brake pedal 2A, and the urgency of the brake control required by the driver can be estimated from the operation speed of the brake pedal 2A. Can do. Then, a criterion for determining whether or not an emergency brake operation is performed can be set as appropriate by any one or combination thereof.

  The anti-lock calculation means 83 determines whether or not anti-lock brake control is necessary based on an input from a wheel speed sensor (not shown). As a determination method, for example, the vehicle body speed is estimated from a wheel speed sensor, the slip ratio of the wheels W1 and W28 is calculated from the vehicle body speed and the wheel speed, and when the slip ratio exceeds a predetermined value, anti-locking is performed. And determining that brake control is necessary.

  The brake control means 84 is input from the emergency brake operation determination means 82 and the antilock calculation means 83, respectively, regarding the brake assist amount, the determination result as to whether or not the emergency brake operation is performed, and the determination result regarding the antilock brake control. The brake control is performed by controlling the operation of the switching valve mechanisms VF and VR, the pump 6, the regulator valve (normally open / close valve) 7, the drag reduction valve (normally open / close valve) 10 and the suction valve 11. Is to do.

When the operation of the brake pedal 2A is performed and the emergency brake operation determination means 82 determines that it is an emergency brake operation, the brake control means 84 generates the brake fluid pressure generated in the master cylinder 2B due to the operation of the brake pedal 2A. In addition, a brake assist amount is appropriately added to perform brake control.
On the other hand, when the operation of the brake pedal 2A is performed and the emergency brake operation determination unit 82 determines that the emergency brake operation is not performed, the brake control unit 84 does not perform the brake assist control.
In any case, when receiving a request for antilock brake control from the antilock calculation means 83, the brake control means 84 performs antilock brake control.

  Further, the controller 8 controls the operation of the switching valve mechanisms VF and VR in a state where the regulator valve 7 is operated and the suction valve 11 is opened and the pump 6 is operated during non-braking operation. Controls such as traction control that eliminates excessive slip of the drive wheels during acceleration and vehicle behavior control (VSA) that stabilizes the behavior of the vehicle by applying different braking forces to the left and right wheels are executed.

  Next, the operation of the brake fluid pressure control device 1 will be described with reference to FIGS. In each operation of the brake fluid pressure control device 1 described below, the controller 8 receives inputs from the master cylinder pressure sensor MS, the wheel speed sensor, and the like, and the switching valve mechanism VF (the first switching valve 41, the second switching valve 41). Switching valve 51), VR (first switching valve 42, second switching valve 52), regulator valve 7, drag reduction valve 10, opening and closing of suction valve 11, and operation of pump 6 (electric motor 16) are appropriately controlled. This is realized.

  In a normal brake operation, as shown in FIG. 1, the regulator valve 7 opens to allow the brake fluid to flow from the master cylinder 2B to the hydraulic pressure path L, and to transfer the hydraulic pressure to the switching valve mechanisms VF and VR. It is in a state to transmit. At this time, in the switching valve mechanisms VF and VR, the first switching valves 41 and 42 are opened, the second switching valves 51 and 52 are closed, and the drag reduction valve 10 and the suction valve 11 are The valve is closed. Therefore, the brake hydraulic pressure generated due to the depression force of the brake pedal 2A is transmitted to the wheel brakes BR1 and BR2 as it is, and a braking force is generated.

The ABS control controls the hydraulic pressure transmitted to the wheel brakes BR1 and BR2 so that the maximum braking effect can be obtained when the wheel is about to enter the locked state while the brake pedal 2A is being depressed. By controlling the hydraulic pressure corresponding to the wheel brake of a wheel that is likely to enter the locked state, the brake hydraulic pressure acting on each wheel brake (not all) may be reduced, increased or constant. It is the control to hold. This ABS control is performed by the controller 8.
Even during this ABS control, HYPERLINK "http://www6.ipdl.ncipi.go.jp/Tokujitu/tjitemdrw.ipdl?N0000=231&N0500=4E#N/;%3e7=;?%3c:;/// & N0001 = 31 & N0552 = 9 & N0553 = 000003 "\ t" tjitemdrw "As shown in FIG. 1, the regulator valve 7 is in a state of allowing the brake fluid to flow from the master cylinder 2B to the hydraulic pressure path L, and the suction valve 11 is closed. It is in a state of excuse.

  In the ABS control, when the brake fluid pressure acting on the wheel brakes BR1 and BR2 is reduced, the first switching valves 41 and 42 are closed in the switching valve mechanisms VF and VR, as shown in FIG. The second switching valves 51 and 52 are opened, and the drag reduction valve 10 is opened. At this time, the regulator valve 7 is opened and the suction valve 11 is closed. As a result, transmission of the brake fluid pressure from the master cylinder 2B of the fluid pressure generating device 2 to the wheel brakes BR1 and BR2 through the fluid pressure path L is interrupted, and the second switching valves 51 and 52 are opened. The brake fluid that has flowed into the wheel brakes BR1 and BR2 flows through the drag reduction valve 10 that is open, flows into the reservoir 3 and is stored therein, and is sucked into the pump 6 and flows through the hydraulic pressure path L. Discharged. As a result, the brake fluid pressure acting on the wheels BR1 and BR2 is reduced.

  Next, when the brake fluid pressure acting on the wheel brakes BR1 and BR2 is maintained in the ABS control, the first switching valves 41 and 42 are closed in the switching valve mechanisms VF and VR as shown in FIG. At the same time, the second switching valves 51 and 52 are closed. At this time, the regulator valve 7 is opened, the suction valve 11 is closed, and the drag reduction valve 10 is opened. As a result, transmission of the brake fluid pressure from the master cylinder 2B of the fluid pressure generating device 2 to the wheel brakes BR1 and BR2 through the fluid pressure path L is interrupted, and the second switching valves 51 and 52 are closed. The brake fluid flowing into the wheels BR1 and BR2 is confined in the hydraulic pressure path closed by the first switching valves 41 and 42, the wheel brakes BR1 and BR2, and the second switching valves 51 and 52, and as a result. The brake fluid pressure acting on the wheels BR1 and BR2 is kept constant.

  In the ABS control, when increasing the brake fluid pressure acting on the wheel brakes BR1 and BR2, as shown in FIG. 1, in the switching valve mechanisms VF and VR, the first switching valves 41 and 42 are opened, The second switching valves 51 and 52 are closed. At this time, the regulator valve 7 is opened, the suction valve 11 is closed, and the drag reduction valve 10 is opened. As a result, the brake hydraulic pressure is transmitted from the master cylinder 2B of the hydraulic pressure generating device 2 to the wheel brakes BR1 and BR2 through the hydraulic pressure path L, and the second switching valves 51 and 52 are closed. The brake fluid pressure generated due to the 2A stepping force is transmitted to the wheel brakes BR1 and BR2 as it is, and as a result, the brake fluid pressure acting on the wheels BR1 and BR2 is increased. At this time, the brake fluid stored in the reservoir 3 is discharged into the hydraulic pressure path L by the pump 6.

  During this ABS control, the electric motor 16 is driven and the pump 6 is operating. Then, the brake fluid is returned to the hydraulic pressure path L by the pump 6. At this time, the damper 13 and the one-way valve 14 absorb the pulsation generated in the hydraulic pressure path L and the like by the operation of the pump 6, and prevent the operation feeling of the brake pedal 2A from deteriorating.

  In this ABS control, when the wheel is about to enter the locked state, the controller 8 controls the operation of the switching valve mechanisms VF and VR, the pump 6, the regulator valve 7 and the drag reducing valve 10 to The maximum braking force is exerted by each wheel brake by repeatedly performing the pressure reduction shown in FIG. 2, the holding of the brake fluid pressure shown in FIG. 3, and the pressure increase shown in FIG.

  Further, in the hydraulic pressurization control such as VSA, as shown in FIG. 4, the switching is performed with the regulator valve 7 closed, the suction valve 11 opened, and the drag reduction valve 10 opened. In the valve mechanisms VF and VR, the opening and closing of the first switching valves 41 and 42 and the second switching valves 51 and 52 are individually controlled, and the brake hydraulic pressure output to each wheel brake is individually controlled. The braking force by the left front wheel brake BR1 and the right rear wheel brake BR2 can be individually controlled. Thereby, in the VSA control, the brake pressure of each wheel can be individually controlled to stabilize the posture of the vehicle. Further, not limited to the VSA control, the controller 8 controls the switching valve mechanisms VF and VR, the pump 6, the regulator valve 7, the drag reducing valve 10, and the suction valve 11 regardless of the operation and the operation amount of the brake pedal of the vehicle driver. The braking force of each wheel can be automatically controlled by controlling the operation of the vehicle.

  In the brake fluid pressure control device of the present invention, the brake fluid of the wheel brakes BR1 and BR2 is sucked by the pump 6 when the brake is not braked, that is, in a state where no depression force is applied to the brake pedal 2A. , The pistons (not shown) of the brake cylinders (not shown) of the wheel brakes BR1 and BR2 are retracted to secure a clearance between the brake pads and the disk rotors (not shown) of the wheels W1 and W2, Drag reduction control for reducing drag of the brake pad is performed.

  In this drag reduction control, as shown in FIG. 5, in the switching valve mechanisms VF and VR, the first switching valves 41 and 42 are closed and the second switching valves 51 and 52 are opened. At this time, the regulator valve 7 is closed, the suction valve 11 is closed, and the drag reduction valve 10 is closed. As a result, transmission of the brake fluid pressure from the master cylinder 2B of the fluid pressure generating device 2 to the wheel brakes BR1 and BR2 through the fluid pressure path L is interrupted, and the second switching valves 51 and 52 are opened. The brake fluid flowing into the wheel brakes BR1 and BR2 is sucked into the pump 6. At this time, since the regulator valve 7 and the suction valve 11 are closed and the first switching valves 41 and 42 are also closed, they are sucked by the pump 6 and discharged to the discharge side connection portion 6a of the hydraulic pressure path L. The brake fluid thus applied flows into the reservoir 3 from the reservoir side connecting portion 3a through the one-way valve 9 through the hydraulic pressure path L and the connecting path 17. At this time, since the drag reducing valve (normally closed on-off valve) 10 is closed, the brake fluid that has flowed in is stored in the reservoir 3. As a result, a clearance is secured between the brake pads of the wheel brakes BR1 and BR2 and the disk rotor (not shown) of the wheels W1 and W2, and dragging of the brake pads is reduced.

  Here, the valve opening pressure of the one-way valve 9 is set higher than the output hydraulic pressure output from the hydraulic pressure generator 2 when the brake operation is maximum. Thus, during normal brake operation and ABS control brake control, the brake fluid does not flow into the reservoir 3 through the one-way valve 9, and in the drag reduction control, that is, when the brake is not braked, In a state where no depressing force is applied to the brake pedal 2A, the brake fluid of the wheel brakes BR1 and BR2 is sucked by the pump 6, and a piston (not shown) of a brake cylinder (not shown) of the wheel brakes BR1 and BR2 is drawn. Only when the control is performed to reduce the drag by securing the clearance between the brake pad and the disk rotor (not shown) of the wheels W1 and W2 by moving the brake pad backward. Through the one-way valve 9, the reservoir-side connection portion 3a flows into the reservoir 3 and is stored. Accordingly, the brake fluid discharge pressure generated by the pump 6 during the drag reduction control is controlled to be higher than the output hydraulic pressure output from the hydraulic pressure generator 2 when the brake operation is maximum.

Next, at the time of the next brake operation, the brake fluid stored in the reservoir 3 is returned to the wheel brakes BR1 and BR2 at the initial stage of the brake operation to reduce the invalid stroke of the brake pedal 2A due to the liquid loss at the initial stage of the brake operation. Brake fluid pressure replenishment control is performed.
In the brake hydraulic pressure replenishment control, as shown in FIG. 1, in the switching valve mechanisms VF and VR, the first switching valves 41 and 42 are opened and the second switching valves 51 and 52 are closed. At this time, the regulator valve 7 is opened, the suction valve 11 is closed, and the drag reduction valve 10 is opened. Thus, the brake fluid stored in the reservoir 3 by the drag reduction control is sucked by the pump 6 through the opened drag reduction valve 10 and is returned to the wheel brakes BR1 and BR2. The recirculated brake fluid causes no fluid loss even in the initial stage of the brake operation, and the invalid stroke of the brake pedal 2A is reduced. At this time, since only the amount of the brake fluid sucked by the pump 6 and stored in the reservoir 3 is discharged from the pump 6 at the previous drag reduction control, there is no excess or deficiency in the discharge amount. The clearance between the rotor and the rotor can be appropriately controlled.

  As described above, in the brake fluid pressure control device 1, the switching valve mechanism VF (first switching valve 41, second switching valve 51), switching valve mechanism VR (first switching valve 42, second switching valve 52), regulator The valve (normally open type on-off valve) 7 and drag reduction valve (normally closed type on-off valve) 10 are controlled to open and close, and the pump 6 is controlled to be output from the master cylinder MS of the hydraulic pressure generator 2. The brake fluid pressure is transmitted to or cut off from the wheel brakes BR1 and BR2, and the brake fluid pressure is released from the wheel brakes BR1 and BR2 to perform other controls such as normal brake operation, ABS control, and VSA. Can do. Further, when the brake is not braked, the brake fluid is sucked from the wheel brakes BR1 and BR2 by a pump to reduce drag in the wheel brakes BR1 and BR2, and the brake fluid sucked through the one-way valve 9 is reduced. In the initial stage of the next brake operation, the brake fluid stored in the reservoir 3 is returned to the master cylinder 2B to reduce the liquid loss in the master cylinder 2B, thereby reducing the invalid stroke of the brake pedal 2A. be able to.

It is a figure explaining the pressure increase control at the time of normal brake operation, and ABS control. It is a figure explaining the pressure reduction control in ABS control. It is a figure explaining the pressure holding control in ABS control. It is a figure explaining pressurization control of brake fluid pressure, such as VSA. It is a figure explaining drag reduction control in a brake fluid pressure control device.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Brake fluid pressure control device 2 Fluid pressure generator 3 Reservoir VF, VR switching valve mechanism 41, 42 1st switching valve 51, 52 2nd switching valve 6 Pump 7 Regulator valve (normally open / close valve)
8 Controller 9 One-way valve 10 Drag reduction valve (normally closed on-off valve)
11 Suction valve 13 Damper 14 One-way valve (check valve)
15 One-way valve (check valve)
16 Electric motor 17 Connection path W1, W2 Wheel BR1 Wheel brake for left front wheel BR2 Wheel brake for right rear wheel MS Master cylinder pressure sensor

Claims (1)

A hydraulic pressure generating device that outputs hydraulic pressure according to the brake operation;
Wheel brakes,
A reservoir,
A first state in which the wheel brake and the hydraulic pressure generating device are connected and a connection between the wheel brake and the reservoir is cut off, and the wheel brake and the reservoir are connected and the wheel brake and the hydraulic pressure are generated. A switching valve mechanism for switching between a second state for shutting off the device;
A pump having a suction side connected to the reservoir and a discharge side connected to a discharge side connection provided in a hydraulic pressure path between the hydraulic pressure generating device and the switching valve mechanism;
A normally open type on-off valve provided between the hydraulic pressure generator and the discharge side connection of the pump;
A brake fluid pressure control device comprising: a controller for controlling the operation of the switching valve mechanism, the pump, and the normally open on-off valve;
A one-way valve that is provided in a connection path that bypasses the pump and connects to a reservoir-side connection portion of the reservoir, and that allows only the flow of working fluid from the discharge side to the suction side of the pump;
An operation controlled by the controller, and a normally closed on-off valve provided between the reservoir side connection part of the connection path and the pump;
With
The brake hydraulic pressure control device, wherein the valve opening pressure of the one-way valve is set higher than the output pressure of the hydraulic pressure generator when the brake operation is maximum.

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