JP2014019339A - Vehicle brake system, and control method for the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a vehicle brake system that can favorably protect an electric motor even when leakage of operating liquid for operating braking means occurs.SOLUTION: A vehicle brake system 10 comprise: a motor cylinder device 16 for letting brake liquid generate liquid pressure according to operation amount of a break pedal 12 operated by a driver by driving an electric motor 72 ; and control means 150 having determination means for determining whether or not liquid leakage of brake liquid occurs. The control means 150 can set a limit either on drive currents supplied to the electric motor 72 or on the liquid pressure generated at the motor cylinder device 16, and when determining that the leakage of the brake liquid occurs, limits the drive current supplied to the electric motor 72. A control method of the vehicle brake system 10 is also disclosed.

Description

  The present invention relates to a vehicle brake system and a control method thereof.

  A brake device (vehicle brake system) that uses an electric motor as a drive source of a booster that boosts the pedaling force when the brake pedal is depressed is widely known, for example, as disclosed in Patent Document 1. .

JP 2010-013069 A

  An electric brake device (brake system for a vehicle) as disclosed in Patent Document 1 is a brake fluid (hydraulic fluid) generated in a motor cylinder in order to suppress heat generation of the electric motor (electric motor) and protect the electric motor. It is also possible to adopt a configuration that restricts the hydraulic pressure of the gas. That is, it is also possible to adopt a configuration in which the electric motor is stopped and the heat generation of the electric motor is suppressed when the hydraulic pressure of the brake fluid reaches the set upper limit. However, in such a configuration, when brake fluid leaks in the hydraulic system, the brake fluid pressure may not increase, and the electric motor may not be stopped properly.

  Therefore, an object of the present invention is to provide a vehicular brake system and a control method therefor that can suitably protect an electric motor when a leakage of hydraulic fluid that operates a brake means occurs.

  In order to solve the above problems, the present invention provides a hydraulic pressure generating means for generating hydraulic pressure in the hydraulic fluid by driving an electric motor according to an operation amount of a brake operation unit operated by a driver, and braking operated by the hydraulic pressure. The vehicle brake system comprises: means; and control means having liquid leakage determination means for determining whether or not there is leakage from the pipeline through which the hydraulic fluid flows. The control means can execute a restriction on a driving current supplied to the electric motor or a restriction on the fluid pressure generated by the fluid pressure generating means, and there is a leakage of the hydraulic fluid from the conduit. The driving current supplied to the electric motor is limited when it is determined.

  According to the present invention, the control means can execute the restriction of the drive current supplied to the electric motor of the hydraulic pressure generating means that generates the hydraulic pressure for operating the braking means or the hydraulic pressure generated by the hydraulic pressure generating means. be able to. And when there is a liquid leak in the conduit through which the working fluid flows, the control means can limit the drive current supplied to the electric motor.

  The control means of the present invention is characterized in that the hydraulic pressure generated by the hydraulic pressure generating means is limited when it is determined that there is no leakage of the hydraulic fluid from the conduit.

  According to the present invention, the control means limits the hydraulic pressure generated by the hydraulic pressure generating means when there is no hydraulic fluid leakage from the conduit, while the drive current supplied to the electric motor when there is liquid leakage. Can be limited.

  Further, the liquid leakage determining means of the present invention is configured such that when the hydraulic pressure corresponding to the operation amount of the brake operation unit is not generated between the hydraulic pressure generating means and the braking means, It is determined that there is a leak.

  According to the present invention, the liquid leakage determining means can determine the presence or absence of liquid leakage based on the hydraulic pressure between the hydraulic pressure generating means and the braking means.

  Further, the control means of the present invention limits the hydraulic pressure or the driving current in order to suppress heat generation of the electric motor when the driving current is supplied to the electric motor for a predetermined time. And

  According to the present invention, the control means can determine that it is necessary to suppress the heat generation of the electric motor when the drive current is supplied to the electric motor for a predetermined time.

  The present invention also includes a hydraulic pressure generating means for generating hydraulic pressure in the hydraulic fluid according to the amount of operation of the brake operating unit operated by the driver by driving the electric motor, and a braking means operating with the hydraulic pressure. The control method is executed by a control means provided in the vehicle brake system. And determining whether or not the hydraulic fluid leaks from the conduit through which the hydraulic fluid flows, and limiting the hydraulic pressure generated by the hydraulic pressure generating means when it is determined that there is no liquid leak And a step of suppressing a drive current supplied to the electric motor when it is determined that the liquid leak is present.

  According to the present invention, the control means includes a step of determining whether or not the hydraulic fluid has leaked, a step of limiting the hydraulic pressure generated by the hydraulic pressure generating means when it is determined that there is no liquid leak, And the step of limiting the drive current supplied to the electric motor when it is determined that the electric motor is present can be executed to protect the electric motor.

  According to the present invention, it is possible to provide a vehicular brake system and a control method therefor that can suitably protect an electric motor when a leakage of hydraulic fluid that operates a braking means occurs.

1 is a schematic configuration diagram of a vehicle brake system according to an embodiment of the present invention. It is a flowchart which shows the procedure of the process in which a control means determines the presence or absence of the brake fluid leak. It is a flowchart which shows the procedure in which a control means performs motor protection. It is an example of the increase / decrease value map which shows the increase / decrease value of the motor protection mode timer with respect to a drive current.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings as appropriate.
FIG. 1 is a schematic configuration diagram of a vehicle brake system according to an embodiment of the present invention.

  The vehicle brake system 10 shown in FIG. 1 transmits a hydraulic signal to a by-wire type brake system that transmits an electrical signal to operate the brake for normal use and a fail-safe type for use. It is configured with both of the traditional hydraulic brake systems that actuate the brakes.

For this reason, as shown in FIG. 1, the vehicle brake system 10 basically includes an input device 14 that inputs an operation when a brake operation unit such as the brake pedal 12 is operated by a driver, and a brake pedal. The pedal stroke sensor St that measures the amount of operation (stroke) when the pedal 12 is depressed, and the electric brake actuator (motor cylinder device 16) that controls (generates) the hydraulic pressure (brake hydraulic pressure) of the brake fluid that is the working fluid. ) And a vehicle behavior stabilization device 18 (hereinafter referred to as VSA (vehicle stability assist) device 18, referred to as VSA; registered trademark) for supporting stabilization of the vehicle behavior.
In the present embodiment, the motor cylinder device 16 serves as a hydraulic pressure generating means for generating a brake hydraulic pressure in the brake fluid that is the hydraulic fluid.

  These input device 14, motor cylinder device 16, and VSA device 18 are connected by, for example, a pipe line (hydraulic pressure path) formed of a pipe material such as a hose or a tube, and a by-wire type brake. As a system, the input device 14 and the motor cylinder device 16 are electrically connected by a harness (not shown).

  Among these, the hydraulic path will be described. The connection port 20a of the input device 14 and the connection point A1 are connected by the first piping tube 22a with reference to the connection point A1 in FIG. 1 (slightly below the center). The output port 24a of the motor cylinder device 16 and the connection point A1 are connected by the second piping tube 22b, and the introduction port 26a of the VSA device 18 and the connection point A1 are connected by the third piping tube 22c.

  With reference to the other connection point A2 in FIG. 1, the other connection port 20b of the input device 14 and the connection point A2 are connected by the fourth piping tube 22d, and the other output port 24b of the motor cylinder device 16 The connection point A2 is connected by the fifth piping tube 22e, and the other introduction port 26b of the VSA device 18 and the connection point A2 are connected by the sixth piping tube 22f.

  The VSA device 18 is provided with a plurality of outlet ports 28a to 28d. The first outlet port 28a is connected to a wheel cylinder 32FR of the disc brake mechanism 30a provided on the right front wheel by a seventh piping tube 22g. The second outlet port 28b is connected to the wheel cylinder 32RL of the disc brake mechanism 30b provided on the left rear wheel by the eighth piping tube 22h. The third outlet port 28c is connected to the wheel cylinder 32RR of the disc brake mechanism 30c provided on the right rear wheel by the ninth piping tube 22i. The fourth outlet port 28d is connected to the wheel cylinder 32FL of the disc brake mechanism 30d provided on the left front wheel by the tenth piping tube 22j.

In this case, the brake fluid is supplied to the wheel cylinders 32FR, 32RL, 32RR, 32FL of the disc brake mechanisms 30a-30d by the piping tubes 22g-22j connected to the outlet ports 28a-28d, and the wheel cylinders 32FR, The wheel cylinders 32FR, 32RL, 32RR, and 32FL are operated by increasing the hydraulic pressure in the 32RL, 32RR, and 32FL, and corresponding wheels (right front wheel, left rear wheel, right rear wheel, left front wheel) A braking force is applied.
That is, in the present embodiment, the wheel cylinders 32FR, 32RL, 32RR, and 32FL serve as braking means that operate with the hydraulic pressure of the brake fluid.

The vehicle brake system 10 can be mounted on various vehicles including, for example, an automobile driven by only an engine (internal combustion engine), a hybrid automobile, an electric automobile, and a fuel cell automobile.
Further, the vehicle brake system 10 can be mounted on vehicles of all drive types without limiting the drive format such as front wheel drive, rear wheel drive, and four wheel drive.

  The input device 14 includes a tandem master cylinder 34 that can generate hydraulic pressure by operating the brake pedal 12 by a driver, and a first reservoir 36 attached to the master cylinder 34. In the cylinder tube 38 of the master cylinder 34, two pistons 40a and 40b spaced apart from each other by a predetermined distance along the axial direction of the cylinder tube 38 are slidably disposed. One piston 40 a is disposed close to the brake pedal 12 and is connected to the brake pedal 12 via a push rod 42. Further, the other piston 40b is arranged farther from the brake pedal 12 than the one piston 40a.

A pair of cup seals 44a and 44b are respectively attached to the outer peripheral surfaces of the one and the other pistons 40a and 40b via annular step portions. Back chambers 48a and 48b communicating with supply ports 46a and 46b, which will be described later, are formed between the pair of cup seals 44a and 44b, respectively. A spring member 50a is disposed between the one and the other pistons 40a and 40b, and another spring member 50b is disposed between the other piston 40b and the side end of the cylinder tube 38. The
The cup seals 44 a and 44 b may be configured to be attached to the inner wall of the cylinder tube 38.

  The cylinder tube 38 of the master cylinder 34 is provided with two supply ports 46a and 46b, two relief ports 52a and 52b, and two output ports 54a and 54b. In this case, each supply port 46a (46b) and each relief port 52a (52b) are provided so as to join and communicate with a reservoir chamber (not shown) in the first reservoir 36, respectively.

  Further, in the cylinder tube 38 of the master cylinder 34, a second pressure chamber 56a and a first pressure chamber 56b for generating a brake fluid pressure corresponding to the depression force of the driver depressing the brake pedal 12 are provided. The second pressure chamber 56a is provided so as to communicate with the connection port 20a via the second hydraulic pressure path 58a, and the first pressure chamber 56b communicates with the other connection port 20b via the first hydraulic pressure path 58b. To be provided.

  A pressure sensor Pm is disposed between the master cylinder 34 and the connection port 20a upstream of the second hydraulic pressure path 58a, and a normally open type is provided downstream of the second hydraulic pressure path 58a. A second shut-off valve 60a composed of a (normally open) solenoid valve is provided. The pressure sensor Pm measures the hydraulic pressure upstream of the second shutoff valve 60a on the master cylinder 34 side on the second hydraulic pressure path 58a.

  Between the master cylinder 34 and the other connection port 20b, on the upstream side of the first hydraulic pressure path 58b, a first shutoff valve 60b composed of a normally open type (normally open type) solenoid valve is provided. A pressure sensor Pp is provided on the downstream side of the first hydraulic pressure path 58b. This pressure sensor Pp measures the hydraulic pressure downstream of the wheel cylinders 32FR, 32RL, 32RR, 32FL from the first shutoff valve 60b on the first hydraulic pressure path 58b.

  The normal open in the second shut-off valve 60a and the first shut-off valve 60b is a valve configured such that the normal position (the position of the valve body when not energized) is in the open position (normally open). Say. In FIG. 1, the second shut-off valve 60 a and the first shut-off valve 60 b respectively show valve closed states in which solenoids are energized and valve bodies (not shown) are activated.

  A branch hydraulic pressure path 58c branched from the first hydraulic pressure path 58b is provided in the first hydraulic pressure path 58b between the master cylinder 34 and the first shutoff valve 60b, and the branched hydraulic pressure path 58c includes A third shut-off valve 62 composed of a normally closed type (normally closed type) solenoid valve and a stroke simulator 64 are connected in series. The normal close in the third shut-off valve 62 refers to a valve configured such that the normal position (the position of the valve body when not energized) is in the closed position (normally closed). In FIG. 1, the third shut-off valve 62 shows a valve open state in which a solenoid (not shown) is actuated by energizing a solenoid.

  The stroke simulator 64 is a device that gives a stroke and a reaction force to the operation of the brake pedal 12 during the by-wire control, and makes the driver feel as if a braking force is generated by a pedaling force. Yes, on the first hydraulic pressure path 58b and on the master cylinder 34 side of the first shutoff valve 60b. The stroke simulator 64 is provided with a hydraulic pressure chamber 65 communicating with the branch hydraulic pressure path 58c, and brake fluid (brake fluid) led out from the first pressure chamber 56b of the master cylinder 34 via the hydraulic pressure chamber 65 is provided. ) Is provided so as to be absorbable.

  The stroke simulator 64 is a simulator that is urged by a first return spring 66a having a high spring constant, a second return spring 66b having a low spring constant, and the first and second return springs 66a and 66b arranged in series. A piston 68, the pedal reaction force of the brake pedal 12 is set to be low when the brake pedal 12 is depressed, and the pedal reaction force of the brake pedal 12 is set high when the brake pedal 12 is depressed late. It is provided to be equivalent to the pedal feeling when the stepping operation is performed.

  The hydraulic pressure path is broadly divided into a second hydraulic pressure system 70a that connects the second pressure chamber 56a of the master cylinder 34 and the plurality of wheel cylinders 32FR and 32RL, a first pressure chamber 56b of the master cylinder 34, and a plurality of pressure paths. The first hydraulic system 70b is connected to the wheel cylinders 32RR and 32FL.

  The second hydraulic system 70a includes a second hydraulic path 58a that connects the output port 54a of the master cylinder 34 (cylinder tube 38) and the connection port 20a in the input device 14, and the connection port 20a of the input device 14 and the motor cylinder. Piping tubes 22a and 22b connecting the output port 24a of the device 16, piping tubes 22b and 22c connecting the output port 24a of the motor cylinder device 16 and the introduction port 26a of the VSA device 18, and a lead-out port of the VSA device 18 The pipe tubes 22g and 22h connect the wheel cylinders 32FR and 32RL to the wheel cylinders 32FR and 32RL, respectively.

  The first hydraulic system 70b includes a first hydraulic path 58b that connects the output port 54b of the master cylinder 34 (cylinder tube 38) in the input device 14 and the other connection port 20b, and another connection port of the input device 14. Piping tubes 22d and 22e that connect 20b and the output port 24b of the motor cylinder device 16, piping tubes 22e and 22f that connect the output port 24b of the motor cylinder device 16 and the introduction port 26b of the VSA device 18, and a VSA device 18 outlet ports 28c, 28d and pipe tubes 22i, 22j for connecting the wheel cylinders 32RR, 32FL, respectively.

  The motor cylinder device 16 includes an actuator mechanism 74 including an electric motor (electric motor 72) and a cylinder mechanism 76 biased by the actuator mechanism 74.

The actuator mechanism 74 is provided on the output shaft 72 b side of the electric motor 72, and a gear mechanism (deceleration mechanism) 78 that transmits a rotational driving force of the electric motor 72 through meshing of a plurality of gears. The ball screw structure 80 includes a ball screw shaft 80a and a ball 80b that move forward and backward along the axial direction when the rotational driving force is transmitted.
In the present embodiment, the ball screw structure 80 is housed in the mechanism housing portion 173 a of the actuator housing 172 together with the gear mechanism 78.

The cylinder mechanism 76 includes a substantially cylindrical cylinder body 82 and a second reservoir 84 attached to the cylinder body 82. The second reservoir 84 is connected to the first reservoir 36 attached to the master cylinder 34 of the input device 14 by a piping tube 86, and the brake fluid stored in the first reservoir 36 is passed through the piping tube 86 to the second reservoir 84. 84 is provided so as to be supplied in the inside. Note that the piping tube 86 may be provided with a tank for storing brake fluid.
An open end (open end) of the cylinder body 82 having a substantially cylindrical shape is fitted into an actuator housing 172 including a housing body 172F and a housing cover 172R, and the cylinder body 82 and the actuator housing 172 are coupled to each other. A cylinder device 16 is configured. Details of the configuration of the actuator housing 172 and the connecting portion between the cylinder body 82 and the actuator housing 172 will be described later.

  In the cylinder body 82, a second slave piston 88a and a first slave piston 88b that are spaced apart from each other by a predetermined distance along the axial direction of the cylinder body 82 are slidably disposed. The second slave piston 88a is disposed in the vicinity of the ball screw structure 80, contacts the one end of the ball screw shaft 80a, and is displaced integrally with the ball screw shaft 80a in the direction of the arrow X1 or X2. The first slave piston 88b is arranged farther from the ball screw structure 80 side than the second slave piston 88a.

Further, the electric motor 72 in the present embodiment is configured to be covered with a motor casing 72a formed separately from the cylinder body 82, and the output shaft 72b slides between the second slave piston 88a and the first slave piston 88b. It arrange | positions so that it may become substantially parallel to (axial direction). That is, the electric motor 72 is arranged so that the axial direction of the output shaft 72b is substantially parallel to the axial direction of the hydraulic pressure control piston.
The rotational drive of the output shaft 72b is transmitted to the ball screw structure 80 via the gear mechanism 78.

The gear mechanism 78 is, for example, a third gear 78a that is attached to the output shaft 72b of the electric motor 72 and a ball 80b that moves the ball screw shaft 80a back and forth in the axial direction about the axis of the ball screw shaft 80a. The gear 78c is composed of three gears, a second gear 78b that transmits the rotation of the first gear 78a to the third gear 78c, and the third gear 78c rotates around the axis of the ball screw shaft 80a. Therefore, the rotation shaft of the third gear 78c is the ball screw shaft 80a, and is substantially parallel to the sliding direction (axial direction) of the hydraulic pressure control piston (the second slave piston 88a and the first slave piston 88b).
As described above, since the output shaft 72b of the electric motor 72 and the axial direction of the hydraulic pressure control piston are substantially parallel, the output shaft 72b of the electric motor 72 and the rotation shaft of the third gear 78c are substantially parallel.

When the rotation shaft of the second gear 78b is configured to be substantially parallel to the output shaft 72b of the electric motor 72, the output shaft 72b of the electric motor 72, the rotation shaft of the second gear 78b, and the rotation shaft of the third gear 78c. Are arranged substantially in parallel.
The actuator mechanism 74 in the present embodiment converts the rotational driving force of the output shaft 72b of the electric motor 72 into the advancing / retreating driving force (linear driving force) of the ball screw shaft 80a by the structure described above. Since the second slave piston 88a and the first slave piston 88b are driven by the ball screw shaft 80a, the actuator mechanism 74 uses the rotational driving force of the output shaft 72b of the electric motor 72 as a hydraulic pressure control piston (second slave piston 88a). And the linear driving force of the first slave piston 88b).
Reference numeral 173a denotes a mechanism storage unit that stores the ball screw structure 80.

A pair of slave cup seals 90a and 90b are attached to the outer peripheral surface of the first slave piston 88b via an annular stepped portion. A first back chamber 94b communicating with a reservoir port 92b described later is formed between the pair of slave cup seals 90a and 90b.
A second return spring 96a is disposed between the second and first slave pistons 88a and 88b, and a first return spring is disposed between the first slave piston 88b and the side end of the cylinder body 82. 96b is disposed.

An annular guide piston 90c that seals between the outer peripheral surface of the second slave piston 88a and the mechanism housing portion 173a in a fluid-tight manner and guides the second slave piston 88a so as to be movable in the axial direction. The cylinder body 82 is provided as a seal member behind the second slave piston 88a. It is preferable that a slave cup seal (not shown) is attached to the inner peripheral surface of the guide piston 90c through which the second slave piston 88a penetrates, and the second slave piston 88a and the guide piston 90c are liquid-tightly configured. Further, a slave cup seal 90b is attached to the front outer peripheral surface of the second slave piston 88a via an annular step portion.
With this configuration, the brake fluid filled in the cylinder body 82 is sealed in the cylinder body 82 by the guide piston 90c and does not flow into the actuator housing 172 side.
A second back chamber 94a communicating with a reservoir port 92a described later is formed between the guide piston 90c and the slave cup seal 90b.

  The cylinder body 82 of the cylinder mechanism 76 is provided with two reservoir ports 92a and 92b and two output ports 24a and 24b. In this case, the reservoir port 92a (92b) is provided so as to communicate with a reservoir chamber (not shown) in the second reservoir 84.

  Further, in the cylinder body 82, a second hydraulic pressure chamber 98a for controlling the brake hydraulic pressure output from the output port 24a to the wheel cylinders 32FR and 32RL side, and the other output port 24b to the wheel cylinders 32RR and 32FL side. A first hydraulic pressure chamber 98b for controlling the output brake hydraulic pressure is provided.

According to this configuration, the second back chamber 94a, the first back chamber 94b, the second hydraulic chamber 98a, and the first hydraulic chamber 98b in which the brake fluid is sealed are brake fluid sealing portions in the cylinder body 82. The guide piston 90c, which functions as a seal member, is partitioned liquid-tight (air-tight) from the mechanism housing portion 173a of the actuator housing 172.
Note that the method of attaching the guide piston 90c to the cylinder body 82 is not limited. For example, the guide piston 90c may be attached with a circlip (not shown).

  A regulating means for regulating the maximum stroke (maximum displacement distance) and the minimum stroke (minimum displacement distance) of the second slave piston 88a and the first slave piston 88b between the second slave piston 88a and the first slave piston 88b. 100 is provided. Further, the first slave piston 88b is provided with a stopper pin 102 that restricts the sliding range of the first slave piston 88b and prevents an overreturn to the second slave piston 88a side. At the time of backup braking at 34, when one system fails, the other system is prevented from failing.

  The VSA device 18 is a well-known one, and a second brake system that controls a second hydraulic system 70a connected to the disc brake mechanisms 30a and 30b (the wheel cylinder 32FR and the wheel cylinder 32RL) of the right front wheel and the left rear wheel. 110a and a first brake system 110b for controlling the first hydraulic system 70b connected to the disc brake mechanisms 30c and 30d (the wheel cylinder 32RR and the wheel cylinder 32FL) of the right rear wheel and the left front wheel. The second brake system 110a is composed of a hydraulic system connected to a disc brake mechanism provided on the left front wheel and the right front wheel, and the first brake system 110b is a disc provided on the right rear wheel and the left rear wheel. A hydraulic system connected to the brake mechanism may be used. Further, the second brake system 110a includes a hydraulic system connected to a disc brake mechanism provided on the right front wheel and the right rear wheel on one side of the vehicle body, and the first brake system 110b includes the left front wheel and the left rear wheel on the vehicle body side. A hydraulic system connected to a disc brake mechanism provided on the wheel may be used.

  Since the second brake system 110a and the first brake system 110b have the same structure, the corresponding parts in the second brake system 110a and the first brake system 110b are assigned the same reference numerals, and The description of the first brake system 110b will be added in parentheses with a focus on the description of the two brake system 110a.

  The second brake system 110a (first brake system 110b) has a common pipe line (first common hydraulic pressure path 112 and second common hydraulic pressure path 114) for the wheel cylinders 32FR, 32RL (32RR, 32FL). Have. The VSA device 18 includes a regulator valve 116 formed of a normally open type solenoid valve disposed between the introduction port 26a and the first common hydraulic pressure path 112, and arranged in parallel with the regulator valve 116 from the introduction port 26a side. A first check valve 118 that permits the flow of brake fluid to the first common hydraulic pressure passage 112 side (blocks the flow of brake fluid from the first common hydraulic pressure passage 112 side to the introduction port 26a side); A first in-valve 120 composed of a normally open type solenoid valve disposed between the common hydraulic pressure path 112 and the first outlet port 28a, and a first inlet valve 120 disposed in parallel with the first inlet valve 120 from the first outlet port 28a side. Allow the brake fluid to flow to the first common hydraulic pressure passage 112 side (from the first common hydraulic pressure passage 112 side to the first outlet port) A second in-valve comprising a second check valve 122 (which prevents the flow of brake fluid to the 8a side) and a normally open type solenoid valve disposed between the first common hydraulic pressure passage 112 and the second outlet port 28b. 124 and the second inlet valve 124 are arranged in parallel to allow the brake fluid to flow from the second lead-out port 28b side to the first common hydraulic pressure path 112 side (second lead-out from the first common hydraulic pressure path 112 side). And a third check valve 126 for inhibiting the flow of brake fluid to the port 28b side.

  Further, the VSA device 18 includes a first out valve 128 including a normally closed solenoid valve disposed between the first outlet port 28a and the second common hydraulic pressure path 114, a second outlet port 28b, and a second outlet port 28b. A second out valve 130 composed of a normally closed solenoid valve disposed between the common hydraulic pressure path 114, a reservoir 132 connected to the second common hydraulic pressure path 114, and a first common hydraulic pressure path 112; It is arranged between the second common hydraulic pressure path 114 and allows the brake fluid to flow from the second common hydraulic pressure path 114 side to the first common hydraulic pressure path 112 side (from the first common hydraulic pressure path 112 side). The fourth check valve 134 (which prevents the flow of brake fluid to the second common hydraulic pressure path 114 side) is disposed between the fourth check valve 134 and the first common hydraulic pressure path 112, and the second common hydraulic pressure path 112 is disposed. A pump 136 that supplies brake fluid from the hydraulic pressure path 114 side to the first common hydraulic pressure path 112 side, an intake valve 138 and a discharge valve 140 provided before and after the pump 136, and a motor M that drives the pump 136, And a suction valve 142 formed of a normally closed solenoid valve disposed between the second common hydraulic pressure path 114 and the introduction port 26a.

In the second brake system 110a, the second hydraulic pressure chamber 98a of the motor cylinder device 16 is output from the output port 24a of the motor cylinder device 16 to a pipe line (hydraulic pressure passage) close to the introduction port 26a. There is provided a pressure sensor Ph for measuring the brake fluid pressure controlled by. Measurement signals measured by the pressure sensors Pm, Pp, and Ph are introduced into the control means 150. The VSA device 18 can also control ABS (anti-lock brake system) in addition to VSA control.
Further, instead of the VSA device 18, a configuration in which an ABS device having only an ABS function is connected may be employed.
The vehicle brake system 10 according to the present embodiment is basically configured as described above. Next, the operation and effect will be described.

  When the vehicle brake system 10 is functioning normally, the second shut-off valve 60a and the first shut-off valve 60b, which are normally open type solenoid valves, are energized to be closed, and the first shut-off valve, which is a normally closed type solenoid valve, is closed. The three shut-off valve 62 is excited and is opened. Accordingly, since the second hydraulic pressure system 70a and the first hydraulic pressure system 70b are blocked by the second cutoff valve 60a and the first cutoff valve 60b, the brake hydraulic pressure generated in the master cylinder 34 of the input device 14 is applied to the disc brake. There is no transmission to the wheel cylinders 32FR, 32RL, 32RR, 32FL of the mechanisms 30a-30d.

  At this time, the brake hydraulic pressure generated in the first pressure chamber 56b of the master cylinder 34 is transmitted to the hydraulic pressure chamber 65 of the stroke simulator 64 via the branch hydraulic pressure path 58c and the third shut-off valve 62 in the valve open state. Is done. When the simulator piston 68 is displaced against the spring force of the first and second return springs 66a and 66b by the brake hydraulic pressure supplied to the hydraulic pressure chamber 65, the stroke of the brake pedal 12 is allowed. A pseudo pedal reaction force is generated and applied to the brake pedal 12. As a result, it is possible to obtain a brake feeling that is comfortable for the driver.

  In such a system state, when the control means 150 detects the depression of the brake pedal 12 by the driver, the control means 150 drives the electric motor 72 of the motor cylinder device 16 to urge the actuator mechanism 74, and the second return spring 96a and The second slave piston 88a and the first slave piston 88b are displaced in the direction of the arrow X1 in FIG. 1 against the spring force of the first return spring 96b. Due to the displacement of the second slave piston 88a and the first slave piston 88b, the brake fluid in the second fluid pressure chamber 98a and the first fluid pressure chamber 98b is pressurized so as to be balanced to generate a desired brake fluid pressure.

Specifically, the control means 150 calculates the depression amount of the brake pedal 12 according to the measured value of the pedal stroke sensor St, and considers the regenerative braking force based on the depression amount (brake operation amount). The target brake fluid pressure (target fluid pressure) is set in step, and the set brake fluid pressure is generated in the motor cylinder device 16.
Then, the brake fluid pressure generated in the motor cylinder device 16 is supplied to the VSA device 18 from the introduction ports 26a and 26b. That is, the motor cylinder device 16 drives the second slave piston 88a and the first slave piston 88b with the rotational driving force of the electric motor 72 that is rotationally driven by an electric signal when the brake pedal 12 is operated, This is a device that generates a brake fluid pressure corresponding to the operation amount and supplies it to the VSA device 18.
Moreover, the electrical signal in this embodiment is a control signal for controlling the electric power which drives the electric motor 72, and the electric motor 72, for example.

  Note that the control unit 150 includes, for example, a microcomputer and peripheral devices including a CPU (Central Processing Unit), a ROM (Read Only Memory), a RAM (Random Access Memory), and the like (not shown). And the control means 150 is comprised so that the program previously memorize | stored in ROM will be expand | deployed to RAM, and it will run with CPU, and will control the brake system 10 for vehicles.

  Further, the operation amount measuring means for measuring the depression operation amount of the brake pedal 12 is not limited to the pedal stroke sensor St, and any sensor that can measure the depression operation amount of the brake pedal 12 may be used. For example, the operation amount measuring means may be a pressure sensor Pm, and the hydraulic pressure measured by the pressure sensor Pm may be converted into a depression operation amount of the brake pedal 12, or the depression operation of the brake pedal 12 may be performed by a depression force sensor (not shown). The structure which measures quantity may be sufficient.

  The brake hydraulic pressure in the second hydraulic pressure chamber 98a and the first hydraulic pressure chamber 98b in the motor cylinder device 16 is supplied to the disc brake mechanism 30a via the first and second inlet valves 120 and 124 in the valve open state of the VSA device 18. To 30d wheel cylinders 32FR, 32RL, 32RR, 32FL, and the wheel cylinders 32FR, 32RL, 32RR, 32FL are actuated to apply a desired braking force to each wheel.

  In other words, in the vehicle brake system 10 according to the present embodiment, when the motor cylinder device 16 that functions as a power hydraulic pressure source, the control means 150 that performs by-wire control, and the like are operable, the driver can use the brake pedal 12. The second shut-off valve 60a and the first shut-off valve communicate with the master cylinder 34 that generates brake fluid pressure by stepping on and the disc brake mechanisms 30a to 30d (wheel cylinders 32FR, 32RL, 32RR, and 32FL) that brake each wheel. A so-called brake-by-wire brake system is activated in which the disc brake mechanisms 30a to 30d are operated with the brake fluid pressure generated by the motor cylinder device 16 in the state of being interrupted at 60b. For this reason, in this embodiment, for example, it can be suitably applied to a vehicle such as an electric vehicle that does not have negative pressure due to an internal combustion engine that has been used for a long time.

  On the other hand, when the motor cylinder device 16 or the like becomes inoperable, the brake generated in the master cylinder 34 with the second shut-off valve 60a and the first shut-off valve 60b opened and the third shut-off valve 62 closed respectively. The hydraulic pressure is transmitted to the disc brake mechanisms 30a to 30d (wheel cylinders 32FR, 32RL, 32RR, and 32FL) to operate the disc brake mechanisms 30a to 30d (wheel cylinders 32FR, 32RL, 32RR, and 32FL). The hydraulic brake system is activated.

For example, a hybrid vehicle or an electric vehicle including a traveling motor (traveling motor) can include a regenerative brake that generates a braking force by regenerative power generation using the traveling motor. When the regenerative brake is operated in such a vehicle, the control means 150 operates at least a traveling motor coupled to any one of the front and rear axles as a generator, and the brake operation amount of the brake pedal 12 (see FIG. 1). The braking force (regenerative braking force) by the regenerative brake is generated according to the above. When the regenerative braking force is insufficient with respect to the brake operation amount of the brake pedal 12 (the braking force requested by the driver), the control means 150 drives the electric motor 72 to generate the braking force by the motor cylinder device 16. . That is, the control means 150 performs regenerative cooperative control by the regenerative brake and the hydraulic brake (motor cylinder device 16). In this case, the control means 150 can be configured to determine the operation amount of the motor cylinder device 16 using a known method.
For example, the brake hydraulic pressure for causing the motor cylinder device 16 to generate a braking force obtained by subtracting the regenerative braking force from the braking force (total braking force) determined in accordance with the brake operation amount of the brake pedal 12 is set to the target hydraulic pressure. The control means 150 sets the operating amount of the motor cylinder device 16 by setting the brake fluid pressure for setting the brake fluid pressure for the motor cylinder device 16 to generate a braking force at a predetermined ratio to the total braking force or the target fluid pressure. What is necessary is just to set it as the structure to determine.

In the vehicular brake system 10 configured as shown in FIG. 1, when the brake pedal 12 is depressed by the driver, the control means 150 measures the operation amount (stroke amount) of the brake pedal 12 by the pedal stroke sensor St. The brake fluid pressure is calculated according to the amount of operation of the brake pedal 12. Furthermore, the control means 150 controls the electric motor 72 of the motor cylinder device 16 so as to generate the calculated brake fluid pressure.
Specifically, the control means 150 drives the electric motor 72 so that the first slave piston 88b and the second slave piston 88a are displaced as much as the calculated brake fluid pressure is generated.
For example, if a map showing the relationship between the brake fluid pressure generated by the motor cylinder device 16 and the voltage (drive voltage) supplied to the electric motor 72 for that purpose is set in advance, the control means 150 will display the map. The drive voltage to be supplied to the electric motor 72 can be calculated with reference. Then, the control means 150 supplies the calculated drive voltage to the electric motor 72 to displace the first slave piston 88b and the second slave piston 88a, and uses the calculated brake fluid pressure as the second brake system 110a of the VSA device 18 and It is generated in the first brake system 110b.

However, when the brake pedal 12 is frequently depressed, a current (driving current) for driving for a long time is supplied to the electric motor 72, and the electric motor 72 is continuously driven. The Further, a drive current is supplied to the electric motor 72 in order to maintain the brake fluid pressure generated by the motor cylinder device 16 even while the brake pedal 12 is depressed. Then, when the drive current is supplied to the electric motor 72 for a long time and the electric motor 72 is driven, there arises a problem that the electric motor 72 generates heat.
Therefore, the control means 150 of the present embodiment protects the electric motor 72 by suppressing the heat generation of the electric motor 72 when the driving current is supplied for a predetermined time and the electric motor 72 is continuously driven. Perform motor protection.
The control means 150 may be configured to calculate the drive current from the configuration of the drive circuit of the electric motor 72 and the supplied drive voltage. Or the structure provided with the ammeter which measures the drive current supplied to the electric motor 72 may be sufficient.

When the control means 150 determines that the motor protection is required to suppress the heat generation of the electric motor 72 when the drive current is supplied to the electric motor 72 over a predetermined time, the upper limit of the brake hydraulic pressure generated in the motor cylinder device 16 is determined. Set value to limit brake fluid pressure. That is, the control unit 150 controls (drives) the electric motor 72 so that the brake fluid pressure generated in the motor cylinder device 16 does not exceed the set upper limit value. This upper limit value may be a brake fluid pressure that can be generated in the motor cylinder device 16 with a driving current that can suppress an excessive temperature rise of the electric motor 72 and that can suitably brake the vehicle. What is necessary is just to set it as the value determined suitably by simulation etc.
As described above, the control unit 150 of the present embodiment is configured to be able to determine whether or not suppression of heat generation (motor protection) of the electric motor 72 is necessary, and has a function as a heat generation suppression determination unit.

  Furthermore, the control means 150 controls (feedback control) the electric motor 72 so that the brake fluid pressure measured by the pressure sensor Ph provided in the second brake system 110a does not exceed the set upper limit value, for example. In this way, the control means 150 sets the upper limit value of the brake fluid pressure and drives the electric motor 72 so as not to exceed the set upper limit value, thereby reducing the load on the electric motor 72 and suppressing heat generation. The motor 72 is protected. And the control means 150 can brake a vehicle suitably. Further, when the valve bodies of the first shut-off valve 60b and the second shut-off valve 60a are configured to close with the downstream brake fluid pressure, the first shut-off is performed even when the brake pedal 12 is depressed with a high pedal effort. The lower limit value of the brake fluid pressure generated by the motor cylinder device 16 is also set so that the valve 60b and the second shutoff valve 60a are closed.

However, for example, when a leakage of brake fluid from a pipeline (hydraulic pressure passage) constituting the second brake system 110a occurs, the brake of the second brake system 110a is driven even when the electric motor 72 of the motor cylinder device 16 is driven. The hydraulic pressure may not increase normally (as set).
In this case, even if the electric motor 72 of the motor cylinder device 16 is driven, the brake fluid pressure of the second brake system 110a does not rise to the set upper limit value, so the control means 150 drives the electric motor 72. I can't stop. That is, even when the drive current is supplied for a predetermined time, the control unit 150 cannot suitably stop the electric motor 72, and the effect of suppressing the heat generation of the electric motor 72 (the electric motor 72 is reduced). Protecting effect) is reduced.

  Therefore, the control unit 150 according to the present embodiment monitors brake fluid leakage in the second brake system 110a. When the control means 150 determines that there is a leakage of brake fluid from the pipeline (hydraulic pressure passage) that constitutes the second brake system 110a, the drive current is supplied to the electric motor 72 for a predetermined time. When this is done, the drive current supplied to the electric motor 72 is limited. Specifically, the control unit 150 sets an upper limit value for the drive current supplied to the electric motor 72 and supplies the drive voltage to the electric motor 72 so that the drive current does not exceed the upper limit value. Such an upper limit value of the driving current (driving voltage) may be a driving current (driving voltage) that can suppress an excessive temperature rise of the electric motor 72, for example, and is appropriately determined by experimental measurement, simulation, or the like. It can be a value.

That is, the control means 150 of the present embodiment limits the drive current (drive voltage) supplied to the electric motor 72 and the brake fluid pressure generated in the motor cylinder device 16 in order to suppress the heat generation of the electric motor 72. One of the restriction and the restriction can be executed.
Thus, in order to suppress the heat generation and protect the electric motor 72, the control unit 150 is configured to be able to execute two methods (limitation of driving current and limitation of brake fluid pressure), thereby allowing one method. Thus, when the heat generation of the electric motor 72 cannot be suppressed, a configuration (so-called fail-safe) that complements the other method can be employed.

For this reason, the control means 150 of this embodiment determines the presence or absence of the leak of the brake fluid from the pipe line (hydraulic pressure path) which comprises the 2nd brake system 110a of the VSA apparatus 18. FIG. That is, the control unit 150 has a function as a liquid leakage determination unit.
FIG. 2 is a flowchart showing a procedure of processing in which the control means determines whether or not there is a leakage of brake fluid. Based on the flowchart shown in FIG. 2, the process by which the control means 150 determines the presence or absence of leakage of the brake fluid will be described (see FIG. 1 as appropriate).

As shown in FIG. 2, the control means 150 determines whether or not the brake pedal 12 has been operated based on the measured value of the pedal stroke sensor St (step S1), and when the brake pedal 12 is not depressed (step S1). → No) terminates the process.
On the other hand, when the control means 150 determines that the brake pedal 12 has been depressed (step S1 → Yes), it calculates the brake fluid pressure according to the amount of operation of the brake pedal 12, and the motor generates the calculated brake fluid pressure. The electric motor 72 of the cylinder device 16 is controlled (step S2).
In step S1, the control means 150 determines that the brake pedal 12 has been depressed when the measured value of the pedal stroke sensor St exceeds a predetermined threshold value.

Further, the control unit 150 determines whether or not the motor protection is being executed (step S3), and if the motor protection is being executed (step S3 → Yes), the process is terminated. Specifically, when the motor protection mode timer “TM_MR_ACT” to be described later is at a predetermined value “MRACT_ON_TM”, the control unit 150 supplies the drive current for a predetermined time and continuously drives the electric motor 72. It is determined that the motor protection is being executed. When the motor protection is not executed (step S3 → No), the control unit 150 advances the process to step S4.
In step S4, the control means 150 compares the brake fluid pressure of the second brake system 110a (that is, the brake fluid pressure measured by the pressure sensor Ph) with the calculated brake fluid pressure. Specifically, it is determined that the motor cylinder device 16 is operating when the brake fluid pressure (measured value) measured by the pressure sensor Ph of the second brake system 110a is smaller than the calculated brake fluid pressure (calculated value). (For example, when the determination is made based on the stroke amount of the first slave piston 88b or the second slave piston 88a or the rotation angle of the electric motor 72) (step S4 → Yes), the control unit 150 determines whether or not there is leakage of the brake fluid. The determination timer (current limit timer “TM_MR_CURLIM”) is incremented (step S5). That is, the control unit 150 adds “1” to the current limit timer “TM_MR_CURLIM”.
Further, when the measured value of the brake fluid pressure is not smaller than the calculated value (step S4 → No), the control unit 150 clears the current limit timer “TM_MR_CURLIM” (step S6). Further, the control means 150 turns “OFF” a flag (current limit flag “F_MR_CURLIM”) for executing the current limit (step S7).

When the current limit timer “TM_MR_CURLIM” exceeds the predetermined upper limit value (step S8 → Yes), the control unit 150 determines that there is a leakage of brake fluid from the hydraulic pressure path constituting the second brake system 110a. Then, the current limit flag “F_MR_CURLIM” is set to “ON” (step S9), and the process is terminated.
On the other hand, when the current limit timer “F_MR_CURLIM” does not exceed the predetermined upper limit value (step S8 → No), the control unit 150 ends the process.
As described above, in step S8, the control unit 150 according to the present embodiment determines whether or not there is a leakage of the brake fluid from the hydraulic pressure path constituting the second brake system 110a based on the value of the current limit timer “TM_MR_CURLIM”.

  The pressure sensor Ph is disposed so as to measure the brake hydraulic pressure between the motor cylinder device 16 (hydraulic pressure generating means) and the wheel cylinders 32FR and 32RL (braking means). Therefore, the control means 150 has a brake fluid leakage when the brake fluid pressure corresponding to the operation amount of the brake operation unit (brake pedal 12) is not generated between the fluid pressure generating means and the braking means. Is determined.

As described above, the control means 150 of the present embodiment mainly executes the processing shown in the procedure from step S1 to step S9 shown in FIG. 2 to form the hydraulic pressure path constituting the second brake system 110a of the VSA device 18. The presence or absence of brake fluid leakage from the vehicle is determined.
When it is determined that there is a leakage of brake fluid from the hydraulic pressure path constituting the second brake system 110a, the current limit flag “F_MR_CURLIM” is set to “ON”.
The process of determining whether or not there is a leakage of brake fluid from the hydraulic pressure path constituting the second brake system 110a, the procedure shown in FIG. 2, for example, is sequentially executed at predetermined intervals (100 msec intervals, etc.). The configuration may be made.

  Then, when the drive current is supplied to the electric motor 72 for a predetermined time, the control unit 150 is configured so that the current limiting flag “F_MR_CURLIM” is “ON”, that is, the hydraulic pressure path constituting the second brake system 110a. When there is a leakage of brake fluid from the motor, the drive current supplied to the electric motor 72 is limited, and when the current limit flag “F_MR_CURLIM” is “OFF”, that is, the brake fluid from the second brake system 110a. When there is no leakage, the brake fluid pressure generated in the motor cylinder device 16 is limited to a preset upper limit value.

FIG. 3 is a flowchart showing a procedure for executing motor protection by the control means, and FIG. 4 is an example of an increase / decrease value map showing an increase / decrease value of the motor protection mode timer with respect to the drive current. Based on the flowchart shown in FIG. 3, the procedure in which the control means 150 performs motor protection is demonstrated (refer FIG. 1 suitably).
As shown in FIG. 3, the control means 150 determines whether or not the brake pedal 12 has been operated based on the measured value of the pedal stroke sensor St (step S10), and when the brake pedal 12 is not depressed (step S10). → No) terminates the process.

When the brake pedal 12 is depressed (step S10 → Yes), the control means 150 calculates the brake fluid pressure corresponding to the operation amount of the brake pedal 12 (step S11), and the calculated brake fluid pressure is The drive current of the electric motor 72 that is generated in the motor cylinder device 16 is calculated (step S12).
For example, the control unit 150 calculates the drive voltage supplied to the electric motor 72 as described above, and further calculates the drive current based on the calculated drive voltage.

Next, the control means 150 refers to the map (increase / decrease value map) shown in FIG. 4 and calculates an increase / decrease value for the calculated drive current (step S13).
This increase / decrease value is a value for increasing / decreasing a variable (motor protection mode timer “TM_MR_ACT”) indicating the progress of a timer for the control means 150 to determine execution of motor protection, and is a design value of the vehicle brake system 10. Is preferably set in advance.

The increase / decrease value map shown as an example in FIG. 4 shows increase / decrease values “K0 to K7” set corresponding to the drive currents whose amperage increases from “I0 (A)” to “I7 (A)”. The increase / decrease value is a value set so as to increase as the drive current increases. In the example of the increase / decrease value map shown in FIG. 4, the increase / decrease value “K0” is the smallest, and “K1”, “K2” It increases in order and “K7” becomes the maximum.
The increase / decrease value “K0” corresponding to a small drive current (eg, “I0 (A)”) is preferably a negative value. As an example, it is preferable that the increase / decrease value corresponding to the drive current “0 (A)” is a negative value.
As described above, when the increase / decrease value of the negative value is set, the motor protection mode timer “TM_MR_ACT” is subtracted when the drive current is small (for example, “0 (A)”). The progress of the timer for determining execution of motor protection is suppressed.
Such increase / decrease values “K0 to K7” are preferably set as appropriate through experimental measurement, simulation, or the like.

  For example, when the calculated drive current is “I5 (A)”, the control unit 150 refers to the increase / decrease value map shown in FIG. 4 and sets the increase / decrease value of the motor protection mode timer “TM_MR_ACT” to “K5”.

When the calculated drive current is a value that is not described in the increase / decrease value map, the control means 150 linearly interpolates the increase / decrease value described in the increase / decrease value map, and the increase / decrease value corresponding to the corresponding drive current. Is calculated.
For example, when the calculated drive current is between “I5 (A)” and “I6 (A)”, the control unit 150 determines that the increase / decrease value “K5” corresponding to “I5 (A)” The increase / decrease value is calculated by linearly interpolating the increase / decrease value “K6” corresponding to “I6 (A)”.

The control means 150 adds the calculated increase / decrease value to the motor protection mode timer “TM_MR_ACT” (step S14). At this time, if the increase / decrease value is a negative value, the calculated increase / decrease value is subtracted from the motor protection mode timer “TM_MR_ACT”.
If the motor protection mode timer “TM_MR_ACT” exceeds the predetermined upper limit value “MRACT_ON_TM” in step S14, the control means 150 sets the motor protection mode timer “TM_MR_ACT” to “MRACT_ON_TM”, and the motor protection mode timer “TM_MR_ACT” When smaller than “0”, the control unit 150 sets the motor protection mode timer “TM_MR_ACT” to “0”. The predetermined upper limit value “MRACT_ON_TM” is preferably set in advance as a design value of the vehicle brake system 10.

When the motor protection mode timer “TM_MR_ACT” is not equal to the upper limit value “MRACT_ON_TM” (step S15 → No), the control unit 150 does not need to suppress the heat generation of the electric motor 72, that is, needs motor protection. If it is determined that there is not, the process is terminated.
In addition, when the motor protection mode timer “TM_MR_ACT” is equal to the upper limit value “MRACT_ON_TM” (step S15 → Yes), the control unit 150 needs to suppress the heat generation of the electric motor 72, that is, the motor protection is necessary. Determination is made and motor protection is executed (step S16).
As described above, in step S15, the control unit 150 of the present embodiment determines whether it is necessary to suppress the heat generation of the electric motor 72 based on the value of the motor protection mode timer “TM_MR_ACT”.

In step S <b> 16, when the current limit flag “F_MR_CURLIM” is “ON”, the control unit 150 limits the drive current to drive the electric motor 72 by limiting the drive voltage supplied to the electric motor 72.
On the other hand, when the current limit flag “F_MR_CURLIM” is “OFF”, the control unit 150 limits the brake fluid pressure so that the brake fluid pressure generated in the motor cylinder device 16 does not exceed the set upper limit value, and controls the electric motor 72. Drive.

As described above, the control unit 150 according to the present embodiment executes the processes shown in the procedures from step S10 to step S16 to determine whether or not motor protection is necessary, and when determining that motor protection is necessary. Performs motor protection.
The process in which the control unit 150 determines the necessity of motor protection shown in the procedure of FIG. 3 may be configured to be sequentially executed at a predetermined interval (100 msec interval, for example).

In the present embodiment, as shown in step S3 of FIG. 2, the control means 150 (see FIG. 1) indicates that the motor protection mode timer “TM_MR_ACT” has a predetermined value “ In the case where it is not “MRACT_ON_TM”, the presence or absence of brake fluid leakage is determined.
However, when the motor protection is executed, that is, when the motor protection mode timer “TM_MR_ACT” is the predetermined upper limit value “MRACT_ON_TM”, the control unit 150 determines whether or not there is a leakage of the brake fluid. It is good.
With this configuration, when the brake fluid leaks when the motor protection is executed and the brake fluid pressure is limited, the control unit 150 drives the electric motor 72 by limiting the drive current. Can be switched.

In the case of such a configuration, for example, even in the case where motor protection is executed in step S3 of FIG. 2 (step S3 → Yes), the flow after step S4 may be executed.
Further, when executing the step S16 of FIG. 3, the control means 150 is driven when it is determined that there is brake fluid leakage (that is, when the current limit flag “F_MR_CURLIM” is “ON”). What is necessary is just to set it as the structure switched so that an electric motor 72 may be driven limiting an electric current.

In the present embodiment, the brake fluid of the second brake system 110a provided with the pressure sensor Ph among the two brake systems (the first brake system 110b and the second brake system 110a) provided in the VSA device 18 shown in FIG. It was set as the structure which determines the presence or absence of liquid leakage.
For example, the second brake system 110a operates normally even if brake fluid leaks from the hydraulic pressure path constituting the first brake system 110b, and the vehicle brake system 10 can exhibit a predetermined braking performance. Further, the brake fluid pressure of the second brake system 110a increases normally (as set) in response to the drive of the electric motor 72 of the motor cylinder device 16. Therefore, when the brake current leaks from the hydraulic pressure path constituting the first brake system 110b, the drive current is supplied to the electric motor 72 for a predetermined time, and the motor protection is required. The means 150 can control the electric motor 72 so that the brake hydraulic pressure of the second brake system 110a does not exceed the set upper limit value, and can protect the motor.

That is, even if brake fluid leaks from the hydraulic pressure path constituting the first brake system 110b, the vehicle brake system 10 can exhibit a predetermined braking performance, and the control means 150 is necessary. Accordingly, motor protection can be suitably executed.
If the current limit continues for a predetermined time or more, the first shut-off valve 60b and the second shut-off valve 60a are opened and the third shut-off valve 62 is closed for backup as in the case of the abnormality described above. Thus, the brake fluid pressure of the master cylinder 34 may be applied to the wheel cylinders 32FR, 32RL, 32RR, 32FL.
From this, in the present embodiment, the control means 150 determines whether or not there is a leakage of brake fluid from the hydraulic pressure path constituting the second brake system 110a, and further from the hydraulic pressure path of the second brake system 110a. When the brake fluid leakage occurs, the control means 150 controls the electric motor 72 so that the brake fluid pressure of the second brake system 110a does not exceed the set upper limit value when motor protection is required. It was set as the structure to do.

However, a configuration may be adopted in which the presence or absence of brake fluid leakage is determined for the two brake systems, the first brake system 110b and the second brake system 110a.
In this case, a pressure sensor is provided on the hydraulic pressure path of the first brake system 110b adjacent to the introduction port 26b, and the control means 150 is based on the brake hydraulic pressure measured by the pressure sensor of the first brake system 110b. What is necessary is just to set it as the structure which determines the presence or absence of the leakage of the brake fluid from the hydraulic path which comprises the 1st brake system 110b.

As described above, the control means 150 of the vehicle brake system 10 according to the present embodiment shown in FIG. 1 determines whether or not there is a leakage of brake fluid from the hydraulic pressure path constituting the second brake system 110a of the VSA device 18. can do. Further, when the drive current is supplied to the electric motor 72 of the motor cylinder device 16 for a predetermined time, the motor protection can be executed to suppress the heat generation of the electric motor 72 and protect the electric motor 72.
When the control means 150 executes the motor protection, and no brake fluid leaks from the fluid pressure path constituting the second brake system 110a, the upper limit set by the brake fluid pressure of the second brake system 110a is set. The electric motor 72 is controlled by limiting the brake fluid pressure so as not to exceed the value.
On the other hand, when the brake fluid leaks from the hydraulic pressure path constituting the second brake system 110a, the drive current supplied to the electric motor 72 is limited to control the electric motor 72.
As a result, the control means 150 causes the drive current to flow even when the brake fluid leaks from the fluid pressure path constituting the second brake system 110a and normal (as set) brake fluid pressure does not occur. By limiting this, it is possible to limit the drive of the electric motor 72, and it is possible to suitably protect the electric motor 72 by suppressing the heat generation of the electric motor 72.

As described above, the control unit 150 of the vehicle brake system 10 according to the present embodiment limits the drive current supplied to the electric motor 72 in order to suppress the heat generation of the electric motor 72 of the motor cylinder device 16; Any one of the restriction | limiting of the brake fluid pressure which the motor cylinder apparatus 16 generate | occur | produces is comprised.
For example, when the controller 150 determines that there is brake fluid leakage from the hydraulic path that forms the second brake system 110 a of the VSA device 18, when the heat generation of the electric motor 72 is suppressed, The drive current supplied to is limited.
As a result, even when the brake fluid pressure is not normally generated (as set) due to the leakage of the brake fluid, the control unit 150 can suitably suppress the heat generation of the electric motor 72.

The present invention is not limited to the above-described embodiment, and can be appropriately changed in design without departing from the spirit of the invention.
For example, the control unit 150 (see FIG. 1) of the present embodiment needs to suppress the heat generation of the electric motor 72 when the drive current is supplied to the electric motor 72 (see FIG. 1) for a predetermined time. Is configured to determine. However, it is not limited to this configuration. For example, a temperature sensor (not shown) that measures the temperature of the electric motor 72 (such as a housing part and a driving part) is provided, and when the measured value of the temperature sensor becomes larger than a predetermined value, the heat generation of the electric motor 72 is generated. It may be configured that the control means 150 determines that it is necessary to suppress this.

10 Brake system for vehicle 12 Brake pedal (brake operation part)
16 Motor cylinder device (hydraulic pressure generating means)
32FR, 32RL, 32RR, 32FL Wheel cylinder (braking means)
72 Electric motor
150 Control means (liquid leak judgment means)

Claims (5)

Hydraulic pressure generating means for generating hydraulic pressure in the hydraulic fluid by driving the electric motor according to the operation amount of the brake operation unit operated by the driver;
Braking means operating at the hydraulic pressure;
Control means having liquid leakage determination means for determining the presence or absence of liquid leakage from the pipeline through which the working fluid flows,
The control means includes
Limiting the drive current supplied to the electric motor or limiting the hydraulic pressure generated by the hydraulic pressure generating means can be executed,
A vehicular brake system that limits the drive current supplied to the electric motor when it is determined that the hydraulic fluid leaks from the pipe. The control means includes
2. The vehicle brake system according to claim 1, wherein the hydraulic pressure generated by the hydraulic pressure generating means is limited when it is determined that there is no leakage of the hydraulic fluid from the pipeline. 3.   The liquid leakage determination means determines that there is a leakage of the hydraulic fluid when the hydraulic pressure corresponding to the operation amount of the brake operation unit is not generated between the hydraulic pressure generation means and the braking means. The vehicle brake system according to claim 1, wherein the vehicle brake system is a vehicle brake system. The control means includes
4. The hydraulic pressure or the drive current is limited to suppress the heat generation of the motor when the drive current is supplied to the motor for a predetermined time. The vehicle brake system according to claim 1. Hydraulic pressure generating means for generating hydraulic pressure in the hydraulic fluid by driving the electric motor according to the operation amount of the brake operation unit operated by the driver;
Braking means operating at the hydraulic pressure;
A control method executed by a control means provided in a vehicle brake system having
Determining the presence or absence of leakage of the hydraulic fluid from a conduit through which the hydraulic fluid flows;
Limiting the fluid pressure generated by the fluid pressure generating means when it is determined that there is no fluid leakage;
Suppressing the drive current supplied to the electric motor when it is determined that the liquid leak is present;
A control method characterized by comprising:

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