JP5273278B2 - Hydro brake control device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a hydraulic-brake control device that maintains desired brake braking force, even when an anti-lock brake is operated, while a brake assist control works. <P>SOLUTION: The hydraulic-brake control device includes: a wheel cylinder that is supplied a working fluid pressurized according to an operation amount of a brake operation member by a driver and applies a braking force to a wheel; a power hydraulic pressure source that pressurizes the working fluid to be supplied to the wheel cylinder; the anti-lock brake that temporally shuts off the supply of the working fluid to the wheel cylinder so as not to lock the wheel; and a brake control unit that performs a predetermined increase pressure processing upon an operation of the anti-lock brake when the working fluid whose pressure is increased at the power hydraulic pressure source is supplied to the wheel cylinder. <P>COPYRIGHT: (C)2012,JPO&amp;INPIT

Description

  The present invention relates to a hydrobrake control device that controls braking force applied to wheels provided in a vehicle.

  As a conventional brake device, there is known a hydrobrake device that can selectively communicate a plurality of brake cylinders, a hydraulic booster, a master cylinder, and a power hydraulic pressure source with a simple circuit, thereby improving controllability. In this hydro brake device, when the system is normal, hydraulic fluid is supplied from the power hydraulic pressure source to the brake cylinder.

  Further, when an abnormality is detected, the control mode is switched to another control mode different from the normal mode, and the brake assist state is set. When the control mode is switched, the open / close states of the plurality of control valves in the brake device are changed. Patent Literature 1 describes a hydrobrake device including a hydrobooster, a master cylinder, a power hydraulic pressure source, and a plurality of brake cylinders.

  Further, when excessive wheel cylinder pressure is generated in the wheel cylinder, the wheel cylinder is connected to the reservoir tank to reduce the wheel cylinder pressure. There is also known a brake fluid pressure control device that electrically connects the master cylinder and the wheel cylinder when the wheel cylinder pressure is appropriately reduced.

  As a result, even if the hydraulic pressure source of the wheel cylinder is switched to the master cylinder, a high-reliability hydrobrake device is provided in which high hydraulic pressure does not flow back from the wheel cylinder to the master cylinder.

  In addition to the brake assist control as described above, there is also known a brake device equipped with an anti-lock brake system that does not lock the wheels of the vehicle. Various anti-lock brake systems have been proposed. In general, the ABS holding valve on the flow path for transmitting hydraulic pressure to the brake is shut off in response to the operation of the wheel to lock.

  And the structure of the anti-lock brake system which intends to prevent the lock | rock of a wheel by interrupting | blocking a high hydraulic pressure temporarily by interrupting an ABS holding valve, and suppressing the braking force of a brake. The control is disclosed in, for example, Patent Document 2 below.

  Furthermore, when a situation where the anti-lock brake should be operated occurs during the operation of the brake assist, the operation of the brake assist is temporarily interrupted and the anti-lock brake is preferentially applied. And after the traffic on the road with a low coefficient of friction is completed and the anti-lock brake operation becomes unnecessary, the brake assist function is functioned again to avoid interference between the brake assist control and the anti-lock brake control, Technologies that attempt proper operation are also known.

  A technique for adjusting the anti-lock brake control and the brake assist control in this way and ensuring a more optimal brake braking force is disclosed in, for example, Patent Document 3 below.

JP 2006-123889 A JP 2007-296908 A JP 2004-276645 A

  However, since the hydraulic pressure of the hydro brake device in a state where the brake assist control is functioning is relatively high, the hydraulic pressure may become unstable due to the operation of the ABS holding valve when the anti-lock brake function is operated at the same time. Concerned. Further, when the hydraulic pressure becomes unstable, there is a concern that accurate hydraulic pressure control and brake assist control become difficult.

  Accordingly, an object of the present invention is to provide a hydrobrake control device that can maintain a desired brake braking force even when an antilock brake is operated in a state where the brake assist control is functioning.

  In order to solve the above-described problems, a hydro brake control device according to an aspect of the present invention is pressurized by a manual hydraulic pressure source that pressurizes a working fluid in accordance with an operation amount of a brake operation member by a driver, and power supply. Connecting a hydraulic power source capable of delivering the working fluid independently from the operation of the brake operating member, the manual hydraulic pressure source and the power hydraulic pressure source, and a wheel cylinder for applying a braking force to the wheel, A plurality of flow paths formed so that hydraulic pressure of the working fluid in the manual hydraulic pressure source and the power hydraulic pressure source can be transmitted to the wheel cylinder, and a plurality of control valves provided in the plurality of flow paths An anti-lock brake system that temporarily shuts off the supply of the working fluid to the wheel cylinder so that the wheels do not lock, and a hydraulic power source of the plurality of control valves A pressure sensor that detects a control pressure of the working fluid supplied to the wheel cylinder, and a control pressure detected by the pressure sensor becomes a target control pressure of the working fluid supplied to the wheel cylinder. A brake control unit that controls opening and closing of the plurality of control valves, and controls the hydraulic pressure of the working fluid that is supplied from at least one of the manual hydraulic pressure source and the power hydraulic pressure source and transmitted to the wheel cylinder; Is provided. The brake control unit is configured to generate a braking force mainly by a hydraulic pressure of a working fluid supplied from the manual hydraulic pressure source to the wheel cylinder, and to generate a braking force larger than the normal braking mode. And a brake assist mode in which brake control is performed mainly by the hydraulic pressure of the working fluid supplied from the power hydraulic pressure source to the wheel cylinder. Further, the brake control unit calculates a control pressure of the working fluid to be supplied to the wheel cylinder from an output value of the pressure sensor when the antilock brake system is activated during execution of the brake assist mode. The brake assist mode may be executed such that the control pressure is regarded as the set target control pressure.

  The hydro brake control device according to another aspect of the present invention includes a manual hydraulic pressure source that pressurizes the working fluid in accordance with an operation amount of the brake operation member by the driver, and the brake fluid that is pressurized by the supply of power. A power hydraulic pressure source that can be sent independently from the operation of the member, the manual hydraulic pressure source and the power hydraulic pressure source, and a wheel cylinder that applies a braking force to a wheel, and the manual hydraulic pressure source and the A plurality of flow paths formed so that the hydraulic pressure of the working fluid in the power hydraulic pressure source can be transmitted to the wheel cylinder, a plurality of control valves provided in the plurality of flow paths, and the wheels do not lock An antilock brake system for temporarily interrupting the supply of the working fluid to the wheel cylinder, and a pressure on the power hydraulic pressure source side of the plurality of control valves, A pressure sensor for detecting a control pressure of the working fluid supplied to the cylinder, and opening and closing the plurality of control valves so that the control pressure detected by the pressure sensor becomes a target control pressure of the working fluid supplied to the wheel cylinder. A brake control unit that controls and controls the hydraulic pressure of the working fluid supplied from at least one of the manual hydraulic pressure source and the power hydraulic pressure source and transmitted to the wheel cylinder. The brake control unit is configured to generate a braking force mainly by a hydraulic pressure of a working fluid supplied from the manual hydraulic pressure source to the wheel cylinder, and to generate a braking force larger than the normal braking mode. And a brake assist mode in which brake control is performed mainly by the hydraulic pressure of the working fluid supplied from the power hydraulic pressure source to the wheel cylinder. Further, the brake control unit calculates a control pressure of the working fluid supplied to the wheel cylinder from an output value of the pressure sensor in a state where the anti-lock brake system is activated during execution of the brake assist mode. The brake assist mode may be executed so that the control pressure becomes a target control pressure that is set as a minimum value for each predetermined period.

  ADVANTAGE OF THE INVENTION According to this invention, it can be set as the hydro brake control apparatus which maintains a desired brake braking force, even if an anti-lock brake act | operates in the state which the brake assist is functioning.

It is a figure which shows the hydrobrake control apparatus which concerns on 1st embodiment of this invention. It is a figure which shows the hydrobrake control apparatus which concerns on 1st embodiment of this invention. It is a figure which illustrates the block configuration of brake ECU concerning the example of operation. It is a figure explaining the operation | movement flow concerning BA control of the operation example 1. FIG. It is a figure which illustrates the block configuration of brake ECU concerning the operation example 2. FIG. It is a figure explaining the operation | movement flow concerning BA control of the operation example 2. FIG. It is a figure which shows notionally the hydraulic system of the hydrobrake control apparatus illustrated in 2nd embodiment.

  The hydrobrake system exemplified in the present embodiment can reduce the deterioration of the braking performance even when the antilock brake system is operated in a state where the brake assist is functioning. This hydrobrake system has a control function of canceling an increase fluctuation detected by a brake fluid pressure detection sensor part (control pressure sensor part) separated from a brake cylinder by an operation of an anti-lock brake system by a pressure increase process or the like.

  As a result, even if an apparent increase in the brake fluid pressure occurs due to the operation of the anti-lock brake system, the brake ECU does not recognize the brake cylinder fluid pressure excessively, and the brake that maintains the original desired braking performance is maintained. Assist control is possible.

  Further, in the embodiment, as a method of canceling the apparently detected increase in brake fluid pressure caused by the ABS operation, the brake ECU performs hydraulic pressure control with the target control pressure calculated by adding the increase variation. . In addition, an example is shown in which the brake ECU holds a minimum value from the output value of the brake fluid pressure detection sensor unit (control pressure sensor unit) and controls it as an output value so as not to detect an apparent rise variation. . Therefore, the first embodiment will be described in detail below with reference to the drawings.

(First embodiment)
FIG. 1 is a diagram for explaining the outline of the configuration of the hydrobrake control device 1 according to the first embodiment. The hydro brake control device 1 includes a brake ECU 70 that controls brake control, and a hydraulic control system 10 that is controlled by the brake ECU 70.

  The hydraulic control system 10 includes a master cylinder hydro booster 31 (master cylinder unit) to which a brake pedal force is transmitted from a brake pedal (typical example of a brake operation member) 24, and a reservoir 34 that supplies control oil to the master cylinder hydro booster 31. A pump 36 and an accumulator pressure sensor 72 are included.

  The hydraulic control system 10 has a switching solenoid 11 for switching the hydraulic system and a control solenoid 12 for controlling the antilock brake operation, and each solenoid operates when the antilock brake is operated. The switching solenoid 11 has a linear valve (STR valve) 66 that opens during brake assist operation and transmits hydraulic pressure from the accumulator 35, and a separation valve (SREA valve) 60.

  The switching solenoid 11 includes a regulator cut valve (SREC valve) 65 that is opened during normal braking operation and transmits hydraulic pressure from the master cylinder hydrobooster 31 and a master cut valve (SMCF valve) 64. A regulator pressure sensor 71 is provided between the master cylinder hydro booster 31 and the regulator cut valve 65. The regulator pressure sensor 71 is a sensor that indicates the pressure of the master cylinder hydro booster 31 corresponding to the depression force of the brake pedal 24.

  The control solenoid 12 includes ABS holding valves 51, 52, 53, and 54 that are opened during a normal brake operation and a brake assist operation and transmit hydraulic pressure from the master cylinder hydro booster 31 and the accumulator 35. The control solenoid 12 includes ABS pressure reducing valves 56, 57, 58, and 59 that are opened when the antilock brake is operated and the like, and reduce the control hydraulic pressure.

  When the brake assist is operated as shown in FIG. 1, the hydraulic pressure of the accumulator 35 is transmitted to the brake caliper 20 along the accumulator path 39 indicated by a thick line in the drawing. The brake caliper 20 has disc brake units 21FR, 21FL, 21RR, and 21RL that perform a brake operation so that a brake pad (not shown) is pressed against the disc by the transmitted hydraulic pressure.

  On the accumulator path 39, a control pressure sensor 73 that detects a hydraulic pressure for controlling the control solenoid 12 is provided between the control solenoid 12 and the switching solenoid 11. The hydraulic pressure value detected by the control pressure sensor 73 is input to the brake ECU 70. Further, the plurality of solenoids provided in the hydraulic control system 10 operate based on a control instruction from the brake ECU 70.

  FIG. 2 is a diagram illustrating the hydrobrake control device 1 according to the first embodiment during a normal brake operation. The hydraulic control system 10 and the brake ECU 70 shown in FIG. 2 have the same configuration as that shown in FIG.

  During the normal brake operation, the hydraulic pressure control system 10 of the hydro brake control device 1 transmits hydraulic pressure from the master cylinder hydro booster 31 to the brake caliper 20 along the normal brake systems 37 and 38 indicated by bold lines in the drawing.

  The control hydraulic pressure transmitted from the master cylinder hydro booster 31 via the normal brake system 37 is transmitted to the disc brake units 21RR and 21RL via the regulator cut valve 65 and the ABS holding valves 53 and 54.

  Further, the control hydraulic pressure transmitted from the master cylinder hydro booster 31 via the normal brake system 37 is transmitted to the disc brake units 21FR and 21FL via the master cut valve 64 and the ABS holding valves 51 and 52. During normal braking operation, the superimposed force from the master cylinder hydro booster 31 is applied to the depression force of the brake pedal 24 to obtain the brake control pressure.

  In particular, as shown in FIG. 1, at the time of emergency braking in which the brake assist function is activated, a large hydraulic pressure is applied to the control solenoid 12 so that a larger braking ability can be exhibited. If the anti-lock brake system is activated with a large hydraulic pressure applied to the control solenoid 12, the ABS holding valves 51, 52, 53 and 54 are closed and shut off, so that the detection value of the control pressure sensor 73 is unstable. It becomes. In general, the detection value of the control pressure sensor 73 is detected by swinging to a larger value side than before the ABS operation.

  The value of the control pressure sensor 73 detected by touching the large value side is a value indicating the control pressure upstream of the ABS holding valves 51, 52, 53 and 54 (on the pressure-increasing linear control valve 66 side). The control pressure transmitted to the brake caliper 20 is on the downstream side (brake caliper 20 side) of the ABS holding valves 51, 52, 53, and 54.

  That is, it is considered that the control pressure detected by the brake ECU 70 by the control pressure sensor 73 when the ABS is operated is a value shifted to a larger value side than the hydraulic pressure actually transmitted to the disc brake units 21FR, 21FL, 21RR and 21RL. The brake ECU 70 recognizes a value larger than the hydraulic pressure actually transmitted to the disc brake units 21FR, 21FL, 21RR and 21RL as a control pressure, and performs hydraulic control of the hydraulic control system 10 based on this large value. .

  That is, the brake ECU 70 is separated from the hydraulic pressure actually transmitted to the disc brake units 21FR, 21FL, 21RR and 21RL, and the detected value of the control pressure sensor 73 showing a large value becomes the control target value of the brake assist control. The hydraulic control system 10 is adjusted.

  If no action is taken in this state, the brake ECU 70 sets the target of the brake ECU 70 based on the detected value of the control pressure sensor 73 temporarily separated from the hydraulic pressure actually transmitted to the disc brake units 21FR, 21FL, 21RR and 21RL. Even if the control pressure value is the same before and after the operation of the ABS, a control for substantially reducing the braking force is performed.

  Therefore, in the hydro brake control device 1 exemplified in the embodiment, the brake ECU 70 performs pressure increase control in consideration of the variation in the value of the control pressure sensor 73 before and after the ABS is operated. An example of the operation of the hydrobrake control device 1 will be described below with reference to the drawings.

(Operation example 1)
FIG. 3 illustrates a block configuration of the brake ECU 70 a according to the operation example 1 of the hydro brake control device 1. 3A, the brake ECU 70a includes a control pressure detection unit 7d to which a control pressure value detected by the control pressure sensor 73 is input. The brake ECU 70a includes an ABS operation detection unit 7a that detects whether or not the antilock brake system is operating.

  The control pressure value of the control pressure sensor 73 recognized by the control pressure detection unit 7d is calculated as a pressure fluctuation value for calculating a fluctuation amount of the control pressure value when the operation of the antilock brake system is detected by the ABS operation detection unit 7a. Input to the unit 7b.

  The pressure fluctuation value calculation unit 7b calculates a pressure fluctuation component Pp-p from the output value of the control pressure sensor 73 that fluctuates as shown in FIG. The pressure fluctuation component Pp-p is a value indicating the difference between the maximum value and the minimum value of the output value of the control pressure sensor 73 within a predetermined period. The pressure fluctuation component Pp-p may be a value indicating a difference between a maximum value and a maximum value, a minimum value and a maximum value, and a maximum value and a minimum value. Since the maximum value or the minimum value can be generally calculated in a shorter time than the maximum value, it is desirable from the viewpoint of quick calculation processing and quick control. On the other hand, if the value indicates the difference between the maximum value and the minimum value within the predetermined period, the pressure fluctuation component with higher reliability can be detected if the predetermined period is set longer. In addition, it is preferable to set the predetermined period short because the pressure fluctuation component can be detected more quickly.

  Then, the BA control target pressure calculation unit 7c adds the pressure fluctuation component Pp-p calculated by the pressure fluctuation value calculation unit 7b, the master cylinder pressure, and the brake assist raising target value. The mass cylinder pressure is detected by the master cylinder pressure detection unit 7i based on the input from the regulator pressure sensor 71, and the brake assist increase target value is calculated by the BA increase target value calculation unit 7j. Further, the hydraulic control system 10 may include a master cylinder pressure sensor (not shown).

  When the brake ECU 70a determines that an assist operation such as emergency braking is necessary, the BA raising target value calculation unit 7j calculates an optimum superimposed pressure component according to the pedal effort input from the brake pedal 24. However, the BA raising target value calculation unit 7j replaces the calculation with the optimum superimposed pressure corresponding to the pedal depression force input from the brake pedal 24, and is stored in a storage unit (not shown) in advance. It is good also as reading from the BA raising target value table. The added BA control target pressure is input to the BA control unit 7e that controls the brake assist operation of the hydraulic control system 10.

  The BA control unit 7e compares the control pressure value of the control pressure sensor 73 input from the control pressure detection unit 7d with the BA control target pressure input from the BA control target pressure calculation unit 7c, and determines the control pressure value. A comparison operation unit 7f is provided for monitoring whether or not the BA control target pressure is reached. When the ABS is activated, the control pressure value of the control pressure sensor 73 tends to be detected as high as the pressure fluctuation component Pp-p. However, since the hydraulic control system 10 changes and sets the target control pressure higher, the hydraulic pressure is reduced. Control operation to be relaxed.

  The BA control unit 7e includes a comparison calculation unit 7f, and the control parameter table stores in advance an optimal control parameter value corresponding to the difference between the BA control target pressure calculated by the comparison calculation unit 7f and the control pressure value. A parameter reading unit 7t for performing reading processing from the BA control parameter table storage unit 7g. The control parameter read by the parameter reading unit 7t is input to the BA control value calculation unit 7h that calculates the actual control current value of each solenoid and each device of the hydraulic control system 10, and is calculated by the BA control value calculation unit 7h. Based on the control current value, the BA controller 7e drives and controls each solenoid and the like.

  The BA control value determined by the processing as described above can perform the brake assist control in which the influence of the increased fluctuation of the control pressure sensor 73 due to the operation of the antilock brake system is reduced. That is, when there is a fluctuation in the detection value of the control pressure sensor 73, the brake ECU 70a controls the value obtained by adding the pressure fluctuation component Pp-p in addition to the mass cylinder pressure and the target value for raising the BA. As a result, the brake assist operation can be performed stably without causing a reduction in braking force.

  Next, the operation | movement flow concerning the operation example 1 of the hydrobrake control apparatus 1 is demonstrated using FIG. FIG. 4 is a diagram illustrating an operation flow relating to the calculation of the BA control target pressure in Operation Example 1.

(Step S41)
The brake ECU 70a determines whether or not it is in a brake assist operating state. If it is in the brake assist operation state, the process proceeds to step S42, and if it is not in the brake assist operation state, it waits in step S41. Note that the BA control unit 7e of the brake ECU 70a uses the brake control pressure value of the control pressure sensor 73 as the master cylinder pressure value indicating the pressure value corresponding to the depression force of the brake pedal 24 and the brake assist when performing the brake assist. Control is performed so as to obtain a pressure value obtained by adding a BA raising target pressure value corresponding to the pressure to be raised. Further, the BA control unit 7e of the brake ECU 70a performs switching processing from the normal brake systems 37 and 38 to the accumulator path 39 when performing brake assist.

(Step S42)
The ABS operation detector 7a of the brake ECU 70a detects whether or not the antilock brake system is operating. If the anti-lock brake system is operating, the process proceeds to step S43, and if the anti-lock brake system is not operating, the process returns to step S41.

(Step S43)
Based on the sensor output value of the control pressure sensor 73, the pressure fluctuation value calculation unit 7b of the brake ECU 70a calculates a pressure fluctuation component Pp-p that is the difference between the maximum value and the minimum value within a predetermined period immediately after the ABS operation. The time required for the pressure fluctuation value calculation unit 7b to calculate the pressure fluctuation component Pp-p is as short as approximately 10 milliseconds or less. For this reason, the calculation time of the pressure fluctuation component Pp-p by the pressure fluctuation value calculation unit 7b does not cause a delay in the brake control of the brake ECU 70a, and can maintain rapid brake drive control.

(Step S44)
The BA control target pressure calculation unit 7c of the brake ECU 70a performs an addition process on the pressure fluctuation component Pp-p calculated in step S43 and the normal brake assist control target pressure (corresponding to the sum of the mass cylinder pressure and the assist lifting amount). The BA control target pressure when the antilock brake system is activated is calculated. Then, the brake ECU 70a performs a hydraulic pressure control process so that the sensor output value of the control pressure sensor 73 becomes the BA control target pressure when the antilock brake system is operated, which is input from the BA control target pressure calculation unit 7c.

  Note that the normal control target values are the mass cylinder pressure indicating the pressure of the master cylinder hydro booster 31 corresponding to the depression force of the brake pedal 24 and the depression force of the brake pedal 24 when the BA control target pressure calculation unit 7c is not operating ABS. The calculation is performed by adding the corresponding BA raising target value.

(Step S45)
The comparison calculation unit 7f of the brake ECU 70a compares the detection value of the control pressure sensor 73 input from the control pressure detection unit 7d with the BA control target pressure input from the BA control target pressure calculation unit 7c, and calculates a difference. To do.

(Step S46)
The parameter reading unit 7t of the brake ECU 70a reads the optimum control parameter based on the difference calculated in step S45, the detected value of the control pressure sensor 73, the BA control target pressure, and the like from the BA control parameter table storage unit 7g. In the BA control parameter table storage unit 7g, an optimal brake assist control parameter table suitable for the vehicle, which is determined in advance in relation to the detection value of the control pressure sensor 73 and the like, is recorded.

  Note that a two-mode brake assist (BA) control parameter table corresponding to the ABS non-operation mode and the ABS operation mode may be prepared and stored in advance in the BA control parameter table storage unit 7g. The parameter reading unit 7t can read the control parameters from the ABS non-operation mode table from the parameters stored in the BA control parameter table storage unit 7g during the brake assist operation in which the ABS does not operate.

  Further, the parameter reading unit 7t can read out the control parameters from the ABS operation mode table during ABS operation from among the parameters stored in the BA control parameter table storage unit 7g.

  In addition, the control parameter stored as the ABS operation mode is determined by measuring a control value in consideration of the pressure fluctuation component Pp-p at the time of operation of the ABS specific to the brake system mounted on the vehicle, and stored. It can be left. In this case, the BA control target pressure calculation unit 7c does not have to perform the calculation process of the BA control target pressure at the time of real-time driving.

  Note that the pressure fluctuation Pp-p specific to the brake system mounted on the vehicle may be obtained by design calculation in advance and obtained by simulation, or a preliminary actual measurement value measured and measured in advance may be used. When the pressure fluctuation component Pp-p due to the ABS operation can be reproduced with high reliability during actual vehicle use or actual braking operation, it is possible to store in the BA control parameter table storage unit 7g in advance and perform read processing. It is preferable from the viewpoint of rapid processing.

(Step S47)
The BA control value calculation unit 7h of the brake ECU 70a calculates a current value for the hydraulic control system 10 to perform a brake assist operation based on the control parameter read in step S46. The current value calculation performed by the BA control value calculation unit 7h is based on a result obtained by performing a simulation in advance or performing measurement measurement or the like in advance. It may be stored in the table storage unit 7g.

  In this case, the parameter reading unit 7t only needs to read and process the necessary control current output value, which is preferable from the viewpoint of shortening the calculation time in the BA control value calculating unit 7h and achieving quick processing.

  The control output value calculated in step S47 is a control output value corresponding to the BA control target pressure obtained by adding the pressure fluctuation calculated in step S44, and is caused by the ABS operation of the control pressure sensor 73. This is a control output value in consideration of the pressure fluctuation.

(Step S48)
The brake ECU 70a detects the pressure detected by the control pressure sensor 73 with the control pressure detection unit 7d. Further, the comparison calculation unit 7f compares the control target value input from the BA control target pressure calculation unit 7c with the detection value detected by the control pressure detection unit 7d, and determines whether or not the desired control target value is obtained. Monitor. That is, the brake ECU 70a performs feedback control in real time so as to obtain a desired hydraulic pressure while monitoring the output value of the control pressure sensor 73. If the detected value is the desired control target value, the process proceeds to step S49. If the detected value is not the desired control target value, the process returns to step S47.

(Step S49)
The ABS operation detection unit 7a of the brake ECU 70a detects whether or not the antilock brake system is released. If the anti-lock brake system is released, the flow is terminated, and if the anti-lock brake system is not released, the process returns to step S43.

  In this operation example 1, even if the control pressure sensor 73 outputs a value that is swung to the high pressure side due to the ABS operation, the brake ECU 70a changes the setting to a target control pressure that is higher by the amount corresponding to the shake output than before the ABS operation. Hydraulically controlled. Therefore, substantially the same brake braking performance can be maintained before and after the ABS operation without performing a control operation for substantially reducing the brake braking force between before and after the ABS operation. Next, an operation example 2 for performing an operation process different from the operation example 1 when the ABS is operated will be described with reference to the drawings.

(Operation example 2)
FIG. 5 illustrates a block configuration of the brake ECU 70 b according to the operation example 2 of the hydro brake control device 1. In FIG. 5A, the brake ECU 70b includes an ABS operation detection unit 7m that detects whether or not the antilock brake system is operated, and a control pressure detection unit 7r to which a control pressure output value of the control pressure sensor 73 is input.

  The output value of the control pressure sensor 73 is detected as a control pressure value by the control pressure detection unit 7r, and then input to the minimum value calculation unit 7n that calculates the minimum value of the sensor output value. A minimum value with respect to the time axis is calculated. The minimum value of the sensor output value calculated by the minimum value calculation unit 7n is input to a minimum value hold calculation unit 7o that holds and outputs the minimum value for a predetermined time. The minimum value hold calculation unit 7o holds the previously input minimum value until the next minimum value is input from the minimum value calculation unit 7n, and outputs the held minimum value to the BA control unit 7k. To do.

  In addition, the BA control unit 7k includes an input value selection unit 7l that appropriately selects a sensor output value input from the control pressure detection unit 7r and a minimum value input from the minimum value hold calculation unit 7o. If the signal for detecting the operation of the antilock brake system is not input from the ABS operation detection unit 7m, the input value selection unit 7l selects the sensor output value of the control pressure sensor 73 input from the control pressure detection unit 7r. Further, when a signal for detecting the operation of the antilock brake system is input from the ABS operation detection unit 7m, the input value selection unit 7l selects the held minimum value input from the minimum value hold calculation unit 7o. That is, when the ABS operates, the BA control unit 7k performs a control operation by replacing the detected value of the control pressure sensor 73 and the hold value of the minimum value.

  Also, the parameter reading unit 7s reads out the optimum BA control parameter corresponding to the input value selected by the input value selection unit 7l from the BA control parameter table storage unit 7p. In the BA control parameter table storage unit 7p, there is a parameter variable table for performing an optimal brake assist operation corresponding to the instruction value of the control pressure sensor 73 or the hold minimum value of the minimum value hold calculation unit 7o in advance. It is recorded.

  The parameter reading unit 7s compares and determines the BA control target pressure that determines the strength level of the brake assist corresponding to the depression force of the brake pedal 24 and the input value selected by the input value selection unit 7l. A control parameter that provides the BA control target pressure may be read. Based on the difference between the BA control target pressure and the input value selected by the input value selection unit 7l so that the input value selected by the input value selection unit 7l becomes the BA control target pressure. It is possible to perform feedback control in which an optimum control parameter is read from the BA control parameter table storage unit 7p. In the second operation example, the BA control target pressure is detected by the BA control unit 7k with the regulator pressure sensor 71 or a master cylinder pressure sensor (not shown) regardless of whether the ABS is in operation or not. It is calculated by adding the master cylinder pressure and the pressure equivalent to raising by brake assist.

  Then, the BA control unit 7k performs hydraulic control so that the BA control target pressure matches the sensor output value of the control pressure sensor 73 when the ABS is not operating. Further, the BA control unit 7k controls the hydraulic pressure so that the BA control target pressure matches the held minimum value when the ABS is operated.

  The BA control value calculation unit 7q calculates an optimal control signal (control current value) based on the variable parameter read by the parameter reading unit 7s, and outputs the control signal to the hydraulic control system 10 to control the hydraulic pressure.

  In the brake ECU 70b exemplified in the operation example 2, the BA control unit 7k performs brake assist hydraulic control based on the input value selected by the input value selection unit 7l. For this reason, even when the output value of the control pressure sensor 73 is apparently increased and detected by the operation of the anti-lock brake system, it is possible to perform hydraulic control with reduced influence.

  Next, the operation flow according to the operation example 2 of the hydro brake control device 1 will be briefly described with reference to FIG. In the following description, since the operation processes already described in the operation example 1 and the like overlap, the description will be omitted or simplified here. FIG. 6 is a diagram for explaining an operation flow related to the BA control in the operation example 2.

(Step S61)
The brake ECU 70b determines whether or not the brake assist operation state is set. If it is in the brake assist operation state, the process proceeds to step S62, and if it is not in the brake assist operation state, it waits in step S61. When the BA control unit 7k of the brake ECU 70b performs the brake assist, the sensor output value obtained by detecting the brake control pressure value of the control pressure sensor 73 by the control pressure detection unit 7r is a pressure corresponding to the depression force of the brake pedal 24. Control is performed so that a master cylinder pressure value indicating a value and a pressure value that is a target for raising the BA corresponding to the pressure to be raised as a brake assist are added. The mass cylinder pressure value is a hydraulic pressure output value of the master cylinder hydro booster 31, and can be detected by an output value of a regulator pressure sensor 71 or a mass cylinder pressure sensor (not shown).

(Step S62)
The ABS operation detector 7m detects whether or not the antilock brake system is operating. If the ABS is operating, the process proceeds to step S63, and if the ABS is not operating, the process returns to step S61.

(Step S63)
The minimum value calculator 7n calculates a minimum value from the output value of the control pressure sensor 73 detected by the control pressure detector 7r. The minimum value calculation unit 7n calculates a minimum value by performing arithmetic processing such as second-order differentiation on time. The minimum value calculator 7n outputs the calculated minimum value to the minimum value hold calculator 7o.

(Step S64)
The minimum value hold calculation unit 7o holds the minimum value calculated by the minimum value calculation unit 7n in step S63, typically until the next minimum value is input, and outputs the hold value to the BA control unit 7k. To do. The minimum value hold calculation unit 7o can arbitrarily set a period for holding the minimum value. For example, the minimum value hold calculation unit 7o can perform hold processing for an arbitrary period, such as holding for each of a plurality of minimum values, instead of the next minimum value. In addition, the minimum value hold calculation unit 7o can perform a desired calculation process such as averaging a plurality of continuous minimum values before and after and output the minimum value. It is preferable to hold or average a plurality of minimum values corresponding to a plurality of values, since the period of the hold values becomes longer, and it is possible to reduce the addition of calculation by the CPU or the like and to perform power-saving control calculation.

  If the average target period for which the minimum value hold calculation unit 7o performs the averaging process is lengthened, it is possible to output a stable value that is averaged to some extent against sudden fluctuations in spike noise. This is preferable because a stable process with less fluctuation can be performed.

  Further, the minimum value hold calculation unit 7o may perform a hold process or the like only on a minimum value equal to or greater than a predetermined curvature. In the case where the vibration frequency of the control pressure sensor is remarkably high, the calculation processing load increases when the minimum value of all fluctuation fluctuations is calculated. Therefore, the so-called thinning-out processing may be performed on the minimum value by various methods. Thereby, it is possible to perform a calculation process quickly and with low power consumption.

(Step S65)
The input value selection unit 7l selects the hold minimum value input from the minimum value hold calculation unit 7o when the antilock brake system is operating. Further, the input value selection unit 7l selects the control pressure sensor output value input from the control pressure detection unit 7r when the antilock brake system is not operating.

(Step S66)
The parameter reading unit 7r reads a necessary variable parameter from the BA control parameter table storage unit 7p based on the output value of the control pressure sensor 73 or the calculated hold minimum value.

  For example, the parameter reading unit 7r reads a control parameter recorded in advance in the BA control parameter table storage unit 7p in association with the calculated hold minimum value. Further, for example, the parameter reading unit 7r reads a control parameter recorded in advance in the BA control parameter table storage unit 7p in association with the difference between the calculated hold minimum value and the control target value.

(Step S67)
The BA control value calculation unit 7q generates and outputs a control signal (control current value) for driving the control solenoid of the hydraulic control system 10 using the parameters read out in step S66, and performs hydraulic control.

(Step S68)
The BA control unit 7k compares the output value of the control pressure sensor 73 or the calculated hold minimum value with the output value of the control pressure sensor 73, and monitors whether the control target value can be controlled. The desired control target value is generally a pressure value obtained by adding a master cylinder pressure value indicating a pressure value corresponding to the depressing force of the brake pedal 24 and a BA raising target pressure value corresponding to the pressure raised as the brake assist. . If the desired control target pressure is reached, the operation flow is temporarily terminated. If the desired control target pressure is not reached, the process returns to step S61.

  The brake ECU 70b shown in the operation example 2 calculates the local minimum value from the detected value even if the vibration is superimposed on the control pressure sensor output value due to the operation of the ABS and is detected as an unstable value, and the vibration vibration equivalent amount is calculated. The pressure value with reduced influence can be calculated. Thereby, the influence of fluctuation vibration of the control pressure sensor output value accompanying the ABS operation is reduced, and a local minimum value closer to a more substantial pressure value is regarded as a control pressure detection value, and the deemed local minimum value becomes a desired target pressure. Can be controlled. Next, brake control of a so-called hybrid electric vehicle will be described in the second embodiment below.

(Second embodiment)
The hydro brake control device 100 according to the second embodiment is mounted on, for example, a hybrid vehicle including an electric motor and an internal combustion engine such as a gasoline engine as a travel drive source. In such a hybrid vehicle, regenerative braking that brakes the vehicle by regenerating kinetic energy of the vehicle into electrical energy and hydraulic braking by the hydrobrake control device 100 can be used for braking the vehicle. In addition, the vehicle in the second embodiment can execute brake regenerative cooperative control in which a desired braking force is generated by using both the regenerative braking and the hydraulic braking together.

  As shown in FIG. 7, the hydro brake control device 100 includes a disc brake unit 210FR, 210FL, 210RR and 210RL provided for each wheel, a master cylinder unit 270, a power hydraulic pressure source 300, a hydraulic pressure, Actuator 400. Here, FIG. 7 is a diagram conceptually showing the hydraulic system of the hydrobrake control device 100 exemplified in the second embodiment.

  Disc brake units 210FR, 210FL, 210RR and 210RL apply braking force to each of the right front wheel, left front wheel, right rear wheel and left rear wheel of the vehicle. The master cylinder unit 270 as a manual hydraulic pressure source is a disc brake unit that applies a brake fluid pressurized in accordance with an operation amount (typically a pedaling force or a stroke stepping amount) by a driver of a brake pedal 240 as a brake operation member. Send to 210FR, 210FL, 210RR and 210RL.

  The power hydraulic pressure source 300 sends the brake fluid as the working fluid pressurized by the power supply to the disc brake units 210FR, 210FL, 210RR and 210RL independently from the operation of the brake pedal 240 by the driver. It is also possible.

  The hydraulic actuator 400 appropriately adjusts the hydraulic pressure of the brake fluid supplied from the power hydraulic pressure source 300 or the master cylinder unit 270 and sends it to the disc brake units 210FR, 210FL, 210RR, and 210RL. Thereby, the braking force with respect to each wheel by hydraulic braking is adjusted.

  Subsequently, each of the disc brake units 210FR, 210FL, 210RR and 210RL, the master cylinder unit 270, the power hydraulic pressure source 300, and the hydraulic actuator 400 will be described in more detail below. Each disc brake unit 210FR, 210FL, 210RR, and 210RL includes a brake disc 220 and wheel cylinders 230FR, 230FL, 230RR, and 230RL built in the brake caliper, respectively.

  Each wheel cylinder 230FR, 230FL, 230RR, and 230RL is connected to the hydraulic actuator 400 via a different fluid passage. In the disc brake units 210FR, 210FL, 210RR, and 210RL, when brake fluid is supplied from the hydraulic actuator 400 to the wheel cylinders 230FR, 230FL, 230RR, and 230RL, a brake pad as a friction member is applied to the brake disc 220 that rotates with the wheels. Is pressed.

  Thereby, a braking force is applied to each wheel. In the second embodiment, the disc brake units 210FR, 210FL, 210RR and 210RL are used. However, for example, other braking force applying mechanisms including wheel cylinders 230FR, 230FL, 230RR and 230RL such as drum brakes are used. Also good.

  In the hydro brake control device 100 shown in FIG. 7, the master cylinder unit 270 is a master cylinder with a hydraulic (hydro) booster, and includes a hydro booster 310, a master cylinder 320, a regulator 330, and a reservoir 340.

  The hydro booster 310 is connected to the brake pedal 240 and amplifies the pedal depression force applied to the brake pedal 240 and transmits it to the master cylinder 320 during the brake assist operation. Further, the brake fluid is supplied from the hydraulic power source 300 to the hydro booster 310 via the regulator 330, whereby the pedal effort is amplified. The master cylinder 320 generates a master cylinder pressure having a predetermined boost ratio with respect to the pedal depression force, and becomes a brake assist operation source.

  A reservoir 340 that stores brake fluid is disposed above the master cylinder 320 and the regulator 330. The master cylinder 320 communicates with the reservoir 340 when the depression of the brake pedal 240 is released.

  On the other hand, the regulator 330 communicates with both the reservoir 340 and the accumulator 350 of the power hydraulic pressure source 300. The reservoir 340 serves as a low pressure source, the accumulator 350 serves as a high pressure source, and a fluid pressure substantially equal to the master cylinder pressure. Is generated.

  Hereinafter, the hydraulic pressure in the regulator 330 is referred to as regulator pressure. In the second embodiment, the master cylinder pressure and the regulator pressure do not have to be exactly the same pressure. For example, the master cylinder unit 270 can be designed so that the regulator pressure is slightly higher. It is.

  Power hydraulic pressure source 300 includes an accumulator 350 and a pump 360. The accumulator 350 converts and stores the pressure energy of the brake fluid boosted by the pump 360 into the pressure energy of an enclosed gas such as nitrogen, for example, about 14 to 22 MPa.

  The pump 360 has a motor 360 a as a drive source, and its suction port is connected to the reservoir 340, while its discharge port is connected to the accumulator 350. The accumulator 350 is also connected to a relief valve 350 a provided in the master cylinder unit 270.

  When the pressure of the brake fluid in the accumulator 350 increases abnormally, for example, about 25 MPa, the relief valve 350 a is opened, and the high-pressure brake fluid is returned to the reservoir 340.

  As described above, the hydro brake control device 100 includes the master cylinder 320, the regulator 330, and the accumulator 350 as a brake fluid supply source for the wheel cylinders 230FR, 230FL, 230RR, and 230RL.

  A master pipe 370 is connected to the master cylinder 320, a regulator pipe 380 is connected to the regulator 330, and an accumulator pipe 390 is connected to the accumulator 350. These master pipe 370, regulator pipe 380 and accumulator pipe 390 are each connected to the hydraulic actuator 400.

  The hydraulic actuator 400 includes an actuator block in which a plurality of flow paths are formed and a plurality of electromagnetic control valves. The flow paths formed in the actuator block include individual flow paths 410, 420, 430 and 440 and a main flow path 450.

  The individual flow paths 410, 420, 430 and 440 are respectively branched from the main flow path 450 and connected to the wheel cylinders 230FR, 230FL, 230RR, 230RL of the corresponding disc brake units 210FR, 210FL, 210RR, 210RL. Thus, each wheel cylinder 230FR, 230FL, 230RR, and 230RL can communicate with the main flow path 450.

  In addition, ABS holding valves 510, 520, 530 and 540 are provided in the middle of the individual flow paths 410, 420, 430 and 440. Each ABS holding valve 510, 520, 530, and 540 has a solenoid and a spring that are ON / OFF controlled, respectively.

  Each ABS holding valve 510, 520, 530, and 540 is a normally open electromagnetic control valve that is opened when each solenoid is in a non-energized state. The ABS holding valves 510, 520, 530, and 540 that are opened can distribute the brake fluid in both directions.

  That is, the brake fluid can flow from the main flow path 450 to the wheel cylinders 230FR, 230FL, 230RR, and 230RL, and conversely, the brake fluid can also flow from the wheel cylinders 230FR, 230FL, 230RR, and 230RL to the main flow path 450. . When the solenoid is energized and the ABS holding valves 510, 520, 530 and 540 are closed, the flow of brake fluid in the individual flow paths 410, 420, 430 and 440 is blocked.

  Further, the wheel cylinders 230FR, 230FL, 230RR, and 230RL are connected to the reservoir channel 550 via pressure reducing channels 460, 470, 480, and 490 connected to the individual channels 410, 420, 430, and 440, respectively. Yes.

  ABS decompression valves 560, 570, 580 and 590 are provided in the middle of the decompression flow paths 460, 470, 480 and 490. Each ABS pressure reducing valve 560, 570, 580, and 590 has a solenoid and a spring that are ON / OFF controlled, respectively. Each of the ABS holding valves 510, 520, 530, and 540 and each of the ABS pressure reducing valves 560, 570, 580, and 590 are control solenoids that perform ABS control.

  Each ABS pressure reducing valve 560, 570, 580 and 590 is a normally closed electromagnetic control valve that is closed when each solenoid is in a non-energized state. When the ABS pressure reducing valves 560, 570, 580 and 590 are closed, the flow of brake fluid in the pressure reducing channels 460, 470, 480 and 490 is blocked.

  When the solenoid is energized and the ABS pressure reducing valves 560, 570, 580, and 590 are opened, the flow of brake fluid in the pressure reducing flow paths 460, 470, 480, and 490 is allowed, and the brake fluid is transferred to the wheel cylinder. From 230 FR, 230 FL, 230 RR and 230 RL, the refrigerant flows back to the reservoir 340 through the pressure reducing channels 460, 470, 480 and 490 and the reservoir channel 550. The reservoir channel 550 is connected to the reservoir 340 of the master cylinder unit 270 via a reservoir pipe 770.

  The main channel 450 has a separation valve 600 in the middle. By this separation valve 600, the main flow channel 450 is divided into a first flow channel 450a connected to the individual flow channels 410 and 420 and a second flow channel 450b connected to the individual flow channels 430 and 440.

  The first flow path 450a is connected to the wheel cylinders 230FR and 230FL on the front wheel side via the individual flow paths 410 and 420. The second flow path 450b is connected to the wheel cylinders 230RR and 230RL on the rear wheel side via the individual flow paths 430 and 440.

  The separation valve 600 is a normally closed electromagnetic control valve that has a solenoid and a spring that are ON / OFF controlled and is closed when the solenoid is in a non-energized state. When the separation valve 600 is in a closed state, the flow of brake fluid in the main flow channel 450 is blocked. When the solenoid is energized and the separation valve 600 is opened, the brake fluid can be circulated bidirectionally between the first flow path 450a and the second flow path 450b.

  In the hydraulic actuator 400, a master channel 610 and a regulator channel 620 that communicate with the main channel 450 are formed. More specifically, the master channel 610 is connected to the first channel 450 a of the main channel 450, and the regulator channel 620 is connected to the second channel 450 b of the main channel 450.

  The master flow path 610 is connected to a master pipe 370 that communicates with the master cylinder 320. Regulator flow path 620 is connected to a regulator pipe 380 that communicates with regulator 330.

  The master channel 610 has a master cut valve 640 in the middle. The master cut valve 640 is provided on the brake fluid supply path from the master cylinder 320 to the wheel cylinders 230FR, 230FL, 230RR, and 230RL.

  The master cut valve 640 has a solenoid and a spring that are controlled to be turned on and off, and the closed state is guaranteed by the electromagnetic force generated by the solenoid upon receipt of a specified control current, so that the solenoid is in a non-energized state. It is a normally open electromagnetic control valve that is opened in some cases.

  The master cut valve 640 that has been opened can cause the brake fluid to flow in both directions between the master cylinder 320 and the first flow path 450 a of the main flow path 450. When a prescribed control current is supplied to the solenoid and the master cut valve 640 is closed, the flow of brake fluid in the master flow path 610 is interrupted.

  Further, a stroke simulator 690 is connected to the master channel 610 via a simulator cut valve 680 on the upstream side of the master cut valve 640. That is, the simulator cut valve 680 is provided in a flow path connecting the master cylinder 320 and the stroke simulator 690.

  The simulator cut valve 680 has a solenoid and a spring that are ON / OFF controlled, and the valve opening state is guaranteed by the electromagnetic force generated by the solenoid upon receipt of a specified control current, and the solenoid is in a non-energized state. It is a normally closed electromagnetic control valve that is closed in some cases.

  When the simulator cut valve 680 is in the closed state, the flow of brake fluid between the master flow path 610 and the stroke simulator 690 is blocked. When the solenoid is energized and the simulator cut valve 680 is opened, the brake fluid can be circulated bidirectionally between the master cylinder 320 and the stroke simulator 690.

  Stroke simulator 690 includes a plurality of pistons and springs, and creates a reaction force according to the depression force of brake pedal 240 by the driver when simulator cut valve 680 is opened. As the stroke simulator 690, it is preferable to employ a stroke simulator having a multistage spring characteristic in order to improve the feeling of brake operation by the driver.

  The regulator channel 620 has a regulator cut valve 650 in the middle. The regulator cut valve 650 is provided on a brake fluid supply path from the regulator 330 to each of the wheel cylinders 230FR, 230FL, 230RR, and 230RL.

  The regulator cut valve 650 also has a solenoid and a spring that are ON / OFF controlled, and the closed state is guaranteed by the electromagnetic force generated by the solenoid when supplied with a prescribed control current, so that the solenoid is in a non-energized state. It is a normally open electromagnetic control valve that is opened in some cases.

  The regulator cut valve 650 in the opened state can cause the brake fluid to flow in both directions between the regulator 330 and the second flow path 450b of the main flow path 450. When the solenoid is energized and the regulator cut valve 650 is closed, the flow of brake fluid in the regulator flow path 620 is blocked.

  In the hydraulic actuator 400, an accumulator channel 630 is also formed in addition to the master channel 610 and the regulator channel 620. One end of the accumulator channel 630 is connected to the second channel 450 b of the main channel 450, and the other end is connected to an accumulator pipe 390 that communicates with the accumulator 350.

  The accumulator flow path 630 has a pressure increasing linear control valve 660 in the middle. Further, the accumulator channel 630 and the second channel 450 b of the main channel 450 are connected to the reservoir channel 550 via the pressure-reducing linear control valve 670.

  The pressure-increasing linear control valve 660 and the pressure-reducing linear control valve 670 each have a linear solenoid and a spring, and both are normally closed electromagnetic control valves that are closed when the solenoid is in a non-energized state. In the pressure-increasing linear control valve 660 and the pressure-decreasing linear control valve 670, the opening degree of the valve is adjusted in proportion to the current supplied to each solenoid.

  Further, the pressure-increasing linear control valve 660 is provided as a common pressure-increasing control valve for each of the wheel cylinders 230FR, 230FL, 230RR and 230RL provided in correspondence with each wheel.

  Similarly, the pressure reducing linear control valve 670 is provided as a pressure reducing control valve common to the wheel cylinders 230FR, 230FL, 230RR, and 230RL. That is, in the hydro brake control device 100, the pressure-increasing linear control valve 660 and the pressure-decreasing linear control valve 670 control supply / discharge of the working fluid sent from the power hydraulic pressure source 300 to the wheel cylinders 230FR, 230FL, 230RR, and 230RL. Are provided as a pair of common control valves.

  If the pressure-increasing linear control valve 660 and the like are made common to the wheel cylinders 230FR, 230FL, 230RR, and 230RL in this way, compared to providing a linear control valve for each wheel cylinder 230FR, 230FL, 230RR, and 230RL, It is preferable from the viewpoint of cost.

  Here, the differential pressure between the inlet and outlet of the pressure increasing linear control valve 660 corresponds to the differential pressure between the pressure of the brake fluid in the accumulator 350 and the pressure of the brake fluid in the main flow channel 450. The differential pressure between the inlet and outlet of the pressure-reducing linear control valve 670 corresponds to the differential pressure between the brake fluid pressure in the main flow channel 450 and the brake fluid pressure in the reservoir 340.

  Further, the electromagnetic driving force according to the power supplied to the linear solenoids of the pressure increasing linear control valve 660 and the pressure reducing linear control valve 670 is F1, the spring biasing force is F2, the pressure increasing linear control valve 66 and the pressure reducing linear control valve Assuming that the differential pressure acting force according to the differential pressure between the inlet and outlet of 670 is F3, the relationship F1 + F3 = F2 is established.

  Therefore, by continuously controlling the power supply (corresponding to F1) to the linear solenoids of the pressure-increasing linear control valve 660 and the pressure-decreasing linear control valve 670, between the inlet and outlet of the pressure-increasing linear control valve 660 and the pressure-decreasing linear control valve 670. Differential pressure (corresponding to F3) can be controlled.

  Further, as shown in FIG. 7, the power hydraulic pressure source 300 and the hydraulic actuator 400 are controlled by a brake ECU 700 as a control unit of the hydro brake control device 100. The brake ECU 700 is configured as a microprocessor including a CPU, and includes a ROM that stores various programs, a RAM that temporarily stores data, an input / output port, a communication port, and the like in addition to the CPU. The CPU may be a multiprocessor having a plurality of processors.

  The brake ECU 700 is configured to be communicable with a host hybrid ECU (not shown) by a bus connection or the like, and the pump of the power hydraulic pressure source 300 is based on control signals from the hybrid ECU and signals from various sensors. 360 and the electromagnetic control valve constituting the hydraulic actuator 400 are controlled.

  When brake assist is functioning according to an instruction from the brake ECU 700, the hydraulic pressure of the accumulator 350 is supplied via the master cylinder unit 270 as a pressure increase source as described above. Then, when the brake assist is functioning and the anti-lock brake system is functioning and the brake ECU 700 shuts off each of the ABS holding valves 510, 520, 530 and 540, spike noise adjustment is added to the detected output value of the control pressure sensor 730. Are shaken.

  As a result, the brake ECU 700 does not change and control the hydraulic pressure of the hydraulic piping provided with the control pressure sensor 730 immediately before the ABS operation and immediately after the ABS operation, but the detection output of the control pressure sensor 730 is caused by the vibration. Detected as a high value.

  In the conventional brake ECU, if it is detected that the detection output value of the control pressure sensor 730 is high, control is performed so that the hydraulic pressure control target value at the time of ABS operation is obtained based on this high value. As a result, immediately after the ABS operation, the brake ECU 700 adjusts and controls the hydraulic pressure of the hydraulic piping provided with the control pressure sensor 730 to decrease, resulting in a reduction in brake braking ability.

  Therefore, the brake ECU 700 exemplified in the second embodiment performs arithmetic processing on the detection output value of the control pressure sensor 730 on which the spike noise-like vibration is superimposed by the ABS operation, and does not cause a decrease in brake braking ability. The control process is as follows. Specifically, the brake ECU calculates the pressure fluctuation component Pp-p of the detection output value of the control pressure sensor 730 when the ABS is actuated during the brake assist operation, and the pressure fluctuation component Pp is calculated as the target control pressure value during the ABS operation. Hydraulic control is performed by adding −p.

In addition, when the ABS is activated when the brake assist is activated, the brake ECU 700 performs second-order differentiation processing or the like on the detection output value of the control pressure sensor 730 to calculate a minimum value. Further, the brake ECU holds the calculated minimum value for a certain period, and performs hydraulic pressure control by regarding the held minimum value as a detection output value of the control pressure sensor 730. Since the held minimum value is a control pressure value in which the influence of the spike noise-like vibration is reduced, the hydraulic control can be performed while the influence by the operation of the ABS is substantially reduced. Therefore, the brake ECU maintains a control target hydraulic pressure value that can exert a desired brake braking force without performing an operation of decreasing the brake control hydraulic pressure due to the output fluctuation of the control pressure sensor 730 due to the operation of the ABS. Control is possible.
The electromagnetic control valve constituting the hydraulic actuator 400 includes ABS holding valves 510, 520, 530 and 540, ABS pressure reducing valves 560, 570, 580 and 590, a separation valve 600, a master cut valve 640, It is assumed that a regulator cut valve 650, a pressure-increasing linear control valve 660, a pressure-decreasing linear control valve 670, and a simulator cut valve 680 are included.

  In addition, a regulator pressure sensor 710, an accumulator pressure sensor 720, a control pressure sensor 730, and a master cylinder pressure sensor 740 are connected to the brake ECU 700. The regulator pressure sensor 710 detects the pressure of the brake fluid in the regulator flow path 620 on the upstream side of the regulator cut valve 650, that is, the regulator pressure, and gives a signal indicating the detected value to the brake ECU 700.

  The accumulator pressure sensor 720 detects the pressure of the brake fluid in the accumulator flow path 630, that is, the accumulator pressure on the upstream side of the pressure-increasing linear control valve 660, and gives a signal indicating the detected value to the brake ECU 700.

  The control pressure sensor 730 detects the pressure of the brake fluid in the first flow path 450a of the main flow path 450, and gives a signal indicating the detected value to the brake ECU 700. Master cylinder pressure sensor 740 detects the pressure in master flow path 610 output from master cylinder 320, and provides a signal indicating the detected value to brake ECU 700. Both the regulator pressure sensor 710 and the master cylinder pressure sensor 740 detect the hydraulic pressure output of the master cylinder unit 270.

  The detection values of the pressure sensors 710, 720, 730, and 740 are sequentially given to the brake ECU 700 every predetermined time, and are stored and held in a predetermined storage area of the brake ECU 700 by a predetermined amount.

  When the separation valve 600 is opened and the first flow path 450a and the second flow path 450b of the main flow path 450 are in communication with each other, the output value of the control pressure sensor 730 is the low pressure of the pressure increase linear control valve 660. This indicates the hydraulic pressure on the high pressure side (upstream side) of the pressure-reducing linear control valve 670 and the output value is used for controlling the pressure-increasing linear control valve 660 and the pressure-reducing linear control valve 670. can do.

  When the pressure increasing linear control valve 660 and the pressure reducing linear control valve 670 are closed and the master cut valve 640 is opened, the output value of the control pressure sensor 730 is the output of the master cylinder pressure sensor 740. It shows the same value as the master cylinder pressure.

  Further, the separation valve 600 is opened so that the first flow channel 450a and the second flow channel 450b of the main flow channel 450 communicate with each other, and the ABS holding valves 510, 520, 530, and 540 are opened, When the ABS pressure reducing valves 560, 570, 580 and 590 are closed, the output value of the control pressure sensor 730 indicates the working fluid pressure acting on each wheel cylinder 230FR, 230FL, 230RR and 230RL, that is, the wheel cylinder pressure. .

  Further, the sensor connected to the brake ECU 700 includes a stroke sensor 250 provided on the brake pedal 240. The stroke sensor 250 detects a pedal stroke as an operation amount of the brake pedal 240, and gives a signal indicating the detected value to the brake ECU 700. The output value of the stroke sensor 250 is also sequentially given to the brake ECU 700 every predetermined time, and is stored and held in a predetermined storage area of the brake ECU 700 by a predetermined amount.

  Note that a brake operation state detection unit other than the stroke sensor 250 may be provided in addition to the stroke sensor 250 or in place of the stroke sensor 250 and connected to the brake ECU 700. Examples of the brake operation state detection means include a pedal depression force sensor that detects an operation force of the brake pedal 240 and a brake switch that detects that the brake pedal 240 is depressed.

  The hydro brake control device 100 configured as described above can execute brake regeneration cooperative control. The hydro brake control device 100 starts braking in response to a braking request. The braking request is generated when a braking force should be applied to the vehicle, for example, when the driver operates the brake pedal 240.

  In response to the braking request, the brake ECU 700 calculates a required braking force, and calculates a required hydraulic braking force that is a braking force to be generated by the hydrobrake control device 100 by subtracting the braking force due to regeneration from the required braking force. Here, the braking force by regeneration is supplied from the hybrid ECU to the hydro brake control device 100.

  Then, the brake ECU 700 calculates target hydraulic pressures of the wheel cylinders 230FR, 230FL, 230RR, and 230RL based on the calculated required hydraulic braking force. The brake ECU 700 determines the value of the control current supplied to the pressure-increasing linear control valve 660 and the pressure-decreasing linear control valve 670 by feedback control so that the wheel cylinder pressure becomes the target hydraulic pressure. That is, the brake ECU 700 controls the pressure increasing linear control valve 660 and the like so that the accumulator pressure corresponding to the calculated required hydraulic braking force can be supplied from the accumulator pipe 390.

  As a result, in the hydro brake control device 100, the brake fluid is supplied from the power hydraulic pressure source 300 to the wheel cylinders 230FR, 230FL, 230RR, and 230RL via the pressure-increasing linear control valve 660, and braking force is applied to the wheels. The Further, brake fluid is discharged from the wheel cylinders 230FR, 230FL, 230RR and 230RL through the pressure-reducing linear control valve 670 as necessary, and the braking force applied to the wheels is adjusted.

  In the second embodiment, the wheel cylinder pressure control system is configured including the power hydraulic pressure source 300, the pressure-increasing linear control valve 660, the pressure-decreasing linear control valve 670, and the like. Braking force control by so-called brake-by-wire is performed by the wheel cylinder pressure control system. The wheel cylinder pressure control system is provided in parallel to the brake fluid supply path from the master cylinder unit 270 to the wheel cylinders 230FR, 230FL, 230RR, and 230RL.

  The hydrobrake control device 100 according to the second embodiment controls the braking force by the wheel cylinder pressure control system even when the required braking force is provided only by the hydraulic braking force without using the regenerative braking force. Can do. Regardless of whether or not the brake regeneration cooperative control is being executed, the control mode for controlling the braking force by the wheel cylinder pressure control system may be referred to as a linear control mode or a brake-by-wire control.

  For example, so-called VSC (Vehicle Stability Control) control, TRC (Traction Control) control, and the like for stabilizing the behavior of the vehicle by suppressing the slip of each wheel on the road surface are executed in the linear control mode. VSC control is control for suppressing the side slip of the wheel at the time of turning of the vehicle. The TRC control is a control for suppressing idling of the drive wheels when the vehicle starts or accelerates. In addition, brake assist control that increases the braking force by supplementing the pedaling force by the driver during emergency braking can also be executed in the linear control mode. In emergency braking, the brake pedal may be depressed at a predetermined speed or higher, the brake pedal may be depressed at a predetermined depression force, or the brake pedal may be depressed at a stroke greater than a predetermined stroke. .

  In the hydro brake control device 100, the brake ECU 700 assists the brake control pressure by increasing the accumulator 350 pressure. The brake ECU 700 monitors the pressure of the control pressure sensor 730 while increasing the pressure increase linear control valve 660 and the pressure decrease linear control valve 670. Is performed by controlling the opening and closing. In the hydro brake control device 100, the brake ECU 700 increases the assist of the brake control pressure by superimposing the accumulator 350 pressure, etc., while the brake ECU 700 monitors the pressure of the regulator pressure sensor 710 according to the output of the stroke sensor 250. This is done by adjusting the pressure. Further, in the hydro brake control device 100, the brake control pressure assist increase control by superimposing the accumulator 350 pressure or the like is performed by the brake ECU 700 according to the output of the stroke sensor 250 while monitoring the pressure of the master cylinder pressure sensor 740. This is done by adjusting the pressure of 320.

  As described above, the hydrobrake control device 100 brakes using the path passing through the accumulator pipe 390 when the brake assist is not operating, and brakes using the path passing through the master pipe 370 and the regulator pipe 380 during the brake assist operation. May be. In the hydro brake control device 100, the state in which the brake assist is performed can be a state in which, in addition to the brake pedal 240, an operation for increasing the braking force is urgently performed, unlike the case of braking by the normal brake pedal 240.

  In addition, the brake ECU 700 gives a target control pressure corresponding to the depression force of the brake pedal 240 in advance or calculates it by calculation. Further, the brake ECU 700 controls the pressure increase linear control valve 660 and the pressure reduction linear control valve 670 to open and close so that the pressure value of the control pressure sensor 730 becomes the target control pressure calculated by the brake ECU 700 or the like. In this case, the target control pressure is obtained by subtracting the amount corresponding to the braking force by regenerative braking from the necessary braking force.

  When the anti-lock brake system (ABS) is activated while the brake assist is activated, the brake ECU 700 performs an operation of closing the ABS holding valves 510, 520, 530, and 540. By this ABS operation, each disk brake unit 210FR, 210FL, 210RR and 210RL applies a braking force to the tire that exceeds the friction braking force between each tire and the road, and the tire is locked. Can be suppressed.

  By the way, when the ABS holding valves 510, 520, 530, and 540 are closed by the operation of the anti-lock brake system, the sensor pressure detection value increases, and the hydraulic control is performed so that the apparent braking performance is lowered as it is. That is, when the ABS holding valves 510, 520, 530 and 540 are closed, the pressure value detected by the control pressure sensor 730 on the upstream side thereof is disturbed or fluctuated due to vibration.

  Typically, when the ABS holding valves 510, 520, 530 and 540 are energized and closed, the control pressure is detected so as to fluctuate to the high pressure side upstream. That is, the detected value of the control pressure sensor 730 is recognized by the brake ECU 700 as a value that has fluctuated to the high pressure side. In general, immediately before the operation of the antilock brake system, the pressure value of the control pressure sensor 730 is controlled by the brake ECU 700 so as to become the target control pressure.

  Therefore, when the valve is operated by the operation of the antilock brake system, the brake ECU 700 recognizes that the output value of the control pressure sensor 730 is higher than the target control pressure value immediately before the ABS operation.

  As a result, the brake ECU 700 controls the pressure-reducing linear control valve 670 and the like to reduce the assist pressure for assisting the brake. Typically, the brake ECU 700 causes the assist pressure transmitted via the accumulator pipe 390 to be reduced by, for example, opening the pressure-reducing linear control valve 670 in a non-energized state. As a result, the braking performance of each of the disc brake units 210FR, 210FL, 210RR, and 210RL is lowered as it is.

  In the second embodiment, the hydro brake control device 100 is configured such that when the anti-lock brake system is operated in the brake assist state in which the pressure is increased by using the hydraulic pressure of the accumulator 350, the brake ECU 700 performs braking performance of the brake. Control the hydraulic pressure so that it does not drop.

  Specifically, the brake ECU 700 performs feedback control by setting the target control pressure value of the control pressure sensor 730 to be higher by the amount corresponding to the pressure fluctuation associated with the operation of the ABS. Also, typically, the brake ECU 700 performs pressure increase control in which the control current of the pressure increase linear control valve 660 is increased by the amount corresponding to the oil pressure fluctuation accompanying the operation of the ABS. In addition, if pressure fluctuations associated with the ABS operation are measured and stored in advance, the stored values are read out, or the pressure fluctuations associated with the ABS operation are detected in real time, thereby adding a current value corresponding to the pressure fluctuation and increasing the pressure. The pressure increase control is performed by increasing the control current of the pressure linear control valve 660.

  Specifically, the brake ECU 700 performs hydraulic pressure control by regarding the value obtained by calculating and holding the minimum value or the minimum value of the detection output value of the control pressure sensor 730 as the detection output value of the control pressure sensor 730. . With this calculation process, even if the detection value of the control pressure sensor 730 increases due to fluctuation, the brake ECU 700 does not substantially recognize the increase.

  The hydro brake control device 100 has two paths for supplying the pressure of the accumulator 350 to the wheel cylinders 230FR, 230FL, 230RR, and 230RL when performing the brake assist control as described above.

  One is that brake fluid is supplied from the power hydraulic pressure source 300 to the hydro booster 310 via the regulator 330, and the hydro booster 310 amplifies the pedal effort applied to the brake pedal 240 and transmits it to the master cylinder 320. It is.

  The other is to transmit from the accumulator 350 to each wheel cylinder 230FR, 230FL, 230RR and 230RL via the pressure-increasing linear control valve 660. One of these two routes may be selectively used at the time of brake assist, or both may be used at the time of brake assist. When both are used at the time of brake assist, since there are a plurality of hydraulic supply systems, the reliability of the brake control is higher than that of a single-path hydraulic supply system, and the brake control can be strong against hydraulic piping failures and the like. I can expect.

  Further, the path for supplying the accumulator 350 pressure via the pressure-increasing linear control valve 660 may be brake assist control only during emergency braking. That is, the hydraulic pressure supply system may be changed in each of the brake assist mode during normal brake operation and the brake assist mode during emergency braking, or the hydraulic pressure supply systems may be the same.

  In the hydro brake control device 100, when the brake assist control is performed by the hydraulic pressure supply system from the master cylinder 320 and the regulator 330, the BA control target pressure after the ABS operation is the mass cylinder pressure, the BA raising target value, and the pressure fluctuation. The value can be obtained by adding the component Pp-p. Further, in the hydro brake control device 100, when the brake control is performed by the hydraulic pressure supply system via the pressure-increasing linear control valve 660, the BA control target pressure after the ABS operation is set to a predetermined setting corresponding to the depression force of the brake pedal 240. The pressure, the target value for raising the BA, and the pressure fluctuation component Pp-p can be added.

  Further, in this case, the brake ECU 700 may set the target control pressure value of the control pressure sensor 730 higher by an amount corresponding to the pressure fluctuation in accordance with the valve opening / closing degree of the pressure increasing linear control valve 660 when the ABS is operated. . When the opening degree of the pressure-increasing linear control valve 660 is large, the assist amount is also large, so that the hydraulic pressure fluctuation due to the ABS operation is also large. Therefore, the amount to be set higher is also increased. Further, since the assist amount is small when the opening degree of the pressure increasing linear control valve 660 is small, it is considered that the hydraulic pressure fluctuation due to the ABS operation is small. Therefore, the amount to be set high is reduced.

  The hydrobrake control device 1 and the hydrobrake control device 100 can be used by appropriately changing the configuration and the operation process within a self-evident range.

1. ・ Hydrobrake control device, 7a ・ ・ ABS operation detection unit, 7b ・ ・ Pressure fluctuation value calculation unit, 7c ・ ・ BA control target pressure calculation unit, 7d ・ ・ Control pressure detection unit, 7e ・ ・ BA control unit, 7f ..Comparison operation unit, 7g ..BA control parameter table storage unit, 7h ..BA control value calculation unit, 7i ..Master cylinder pressure detection unit, 7j ..BA raising target value calculation unit, 7k ..BA control・ 7l ・ ・ Input value selection unit, 7m ・ ・ ABS operation detection unit, 7n ・ ・ Minimum value calculation unit, 7o ・ ・ Minimum value hold calculation unit, 7p ・ ・ BA control parameter table storage unit, 7q ・ ・ BA control Value calculation unit, 7r ... Control pressure detection unit, 7s ... Parameter reading unit, 7t ... Parameter reading unit, 10 .... Hydraulic control system, 11 .... Switching solenoid, 12 .... Control solenoid, 20 .... Bray Caliper, 21FR · · disc brake unit, 21RR · · disc brake unit, 24 · · brake pedal, 31 · · master cylinder hydro booster, 34 · · reservoir, 35 · · accumulator, 36 · · pump, 37 · · · normal brake System, 39 ... Accumulator path, 51 ... ABS holding valve, 56 ... ABS pressure reducing valve, 64 ... Master cut valve, 65 ... Regulator cut valve, 66 ... Pressure increasing linear control valve, 70 ... Brake ECU 70a ··· Brake ECU, 70b · · Brake ECU, 71 · · Regulator pressure sensor, 72 · · Accumulator pressure sensor, 73 · · Control pressure sensor.

Claims (2)

A manual hydraulic pressure source that pressurizes the working fluid according to the amount of operation of the brake operation member by the driver;
A hydraulic power source capable of delivering the working fluid pressurized by the supply of power independently from the operation of the brake operation member;
The manual hydraulic pressure source and the power hydraulic pressure source are connected to a wheel cylinder for applying a braking force to the wheel, and the hydraulic pressure of the working fluid in the manual hydraulic pressure source and the power hydraulic pressure source is transmitted to the wheel cylinder. A plurality of flow passages formed so as to be capable of;
A plurality of control valves provided in the plurality of flow paths;
An anti-lock brake system that temporarily shuts off the supply of the working fluid to the wheel cylinder so that the wheel does not lock;
A pressure sensor for detecting a control pressure of the working fluid supplied to the wheel cylinder, the pressure being on the power hydraulic pressure source side of the plurality of control valves;
Controlling the opening and closing of the plurality of control valves so that the control pressure detected by the pressure sensor becomes the target control pressure of the working fluid supplied to the wheel cylinder, and at least one of the manual hydraulic pressure source and the power hydraulic pressure source A brake control unit that controls the hydraulic pressure of the working fluid that is supplied from and transmitted to the wheel cylinder,
The brake control unit
A normal brake mode in which a braking force is generated mainly by the hydraulic pressure of the working fluid supplied from the manual hydraulic pressure source to the wheel cylinder;
When generating a braking force larger than that in the normal brake mode, a brake assist mode in which brake control is performed mainly by the hydraulic pressure of the working fluid supplied from the power hydraulic pressure source to the wheel cylinder can be executed. Has been
Further, the brake control unit calculates a control pressure of the working fluid to be supplied to the wheel cylinder from an output value of the pressure sensor when the antilock brake system is activated during execution of the brake assist mode. The brake assist mode is executed so that the control pressure becomes the set target control pressure.
Hydro brake control device characterized by that. A manual hydraulic pressure source that pressurizes the working fluid according to the amount of operation of the brake operation member by the driver;
A hydraulic power source capable of delivering the working fluid pressurized by the supply of power independently from the operation of the brake operation member;
The manual hydraulic pressure source and the power hydraulic pressure source are connected to a wheel cylinder for applying a braking force to the wheel, and the hydraulic pressure of the working fluid in the manual hydraulic pressure source and the power hydraulic pressure source is transmitted to the wheel cylinder. A plurality of flow passages formed so as to be capable of;
A plurality of control valves provided in the plurality of flow paths;
An anti-lock brake system that temporarily shuts off the supply of the working fluid to the wheel cylinder so that the wheel does not lock;
A pressure sensor for detecting a control pressure of the working fluid supplied to the wheel cylinder, the pressure being on the power hydraulic pressure source side of the plurality of control valves;
Controlling the opening and closing of the plurality of control valves so that the control pressure detected by the pressure sensor becomes the target control pressure of the working fluid supplied to the wheel cylinder, and at least one of the manual hydraulic pressure source and the power hydraulic pressure source A brake control unit that controls the hydraulic pressure of the working fluid that is supplied from and transmitted to the wheel cylinder,
The brake control unit
A normal brake mode in which a braking force is generated mainly by the hydraulic pressure of the working fluid supplied from the manual hydraulic pressure source to the wheel cylinder;
When generating a braking force larger than that in the normal brake mode, a brake assist mode in which brake control is performed mainly by the hydraulic pressure of the working fluid supplied from the power hydraulic pressure source to the wheel cylinder can be executed. Has been
Further, the brake control unit calculates a control pressure of the working fluid to be supplied to the wheel cylinder from an output value of the pressure sensor when the antilock brake system is activated during execution of the brake assist mode. The brake assist mode is executed so that the control pressure becomes the set target control pressure.
Hydro brake control device characterized by that.

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