JP5304632B2 - Brake control device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide technology capable of attaining the enhancement of liquid pressure responsiveness in a brake control device including an electronic control type brake. <P>SOLUTION: The brake control device generates liquid pressure on a wheel cylinder by feeding a braking fluid through a liquid pressure circuit according to the operation of a brake pedal and gives a brake force to a wheel by the liquid pressure. The control device includes a stroke sensor for detecting a stroke of the brake pedal; a wheel cylinder pressure sensor for detecting wheel cylinder pressure; and a brake ECU for calculating the target liquid pressure d of the wheel cylinder based on an amount of the stroke of the brake pedal and adjusting it so that the liquid pressure of the wheel cylinder is brought close to the target liquid pressure d. The brake ECU can execute usual adjustment for adjusting the liquid pressure of the wheel cylinder using a detection liquid pressure value e of the wheel cylinder pressure sensor and correction adjustment for adjusting the liquid pressure of the wheel cylinder using a correction value obtained by reducing and correcting the detection liquid pressure value e. <P>COPYRIGHT: (C)2011,JPO&amp;INPIT

Description

  The present invention relates to a brake control device.

  Conventionally, an electronically controlled brake (ECB) that adjusts the hydraulic pressure supplied to each wheel cylinder by electronically controlling the brake fluid supply to multiple wheel cylinders via a hydraulic circuit has been provided. Brake control devices are known.

  Generally, such a brake control device includes a hydraulic circuit that connects a reservoir tank that stores brake fluid and each wheel cylinder, and a pump that sucks and discharges brake fluid in the reservoir tank and pressurizes each wheel cylinder. Prepare. The hydraulic pressure circuit is provided with a hydraulic pressure sensor that detects the hydraulic pressure of each wheel cylinder. In addition, the brake control device includes a master cylinder provided so that a brake pedal can enter, a flow path that connects the master cylinder and the wheel cylinder, and a stroke sensor that detects a stroke amount of the brake pedal. The flow path connecting the master cylinder and the wheel cylinder contains the brake fluid sent from the master cylinder by the operation of the brake pedal and generates a reaction force according to the operation of the brake pedal. A master cut valve that shuts off the flow of brake fluid to the wheel cylinder is provided.

  In such a configuration, when the brake pedal is depressed, the brake ECU calculates the target hydraulic pressure of the wheel cylinder corresponding to the stroke amount of the brake pedal, and from the reservoir tank so that the wheel cylinder pressure becomes the target hydraulic pressure. Brake fluid is supplied to each wheel cylinder. The amount of brake fluid supplied to the wheel cylinder is feedback-adjusted based on the detected hydraulic pressure value of the hydraulic pressure sensor.

  Further, when the brake pedal is depressed, the master cut valve is closed, and the flow of brake fluid from the master cylinder to the wheel cylinder is interrupted. Then, the brake fluid flows from the master cylinder into the stroke simulator, and a reaction force corresponding to the depression of the brake pedal is generated by the stroke simulator. As a result, the brake pedal is provided with a feeling of resistance corresponding to the increase in the wheel cylinder pressure to give the driver a good brake feeling.

  Patent Document 1 includes a depression amount detecting means for detecting a depression amount of a brake pedal and a hydraulic pressure detection element for detecting a hydraulic pressure of a wheel, and an output of the hydraulic pressure detection element is set in advance corresponding to the depression amount of the brake pedal. There is disclosed a failure determination device for a braking device that determines that a hydraulic pressure detection element has failed when it differs from the measured value.

Japanese Patent Laid-Open No. 1-269656

  In the above-described brake control device, the master cut valve is open when the brake pedal is not operated in order to reliably release the hydraulic pressure of the wheel cylinder in a state where no braking force is applied to the wheel. . Therefore, a normally open electromagnetic control valve that is normally closed in a power supply state and opened in a non-power supply state is used as the master cut valve. When the brake pedal is depressed, the brake ECU receives a signal from the stroke sensor, detects that the brake pedal has been depressed, and supplies a control current so that the master cut valve is closed. As a result, the master cut valve is closed and the flow of brake fluid from the master cylinder to the wheel cylinder is shut off.

  In such a configuration, a time lag occurs between the start of the depression of the brake pedal and the closing of the master cut valve due to the time required for the arithmetic processing of the brake ECU and the response time of the master cut valve. Therefore, a part of the brake fluid sent from the master cylinder when the brake pedal is depressed may flow to the wheel cylinder side via the master cut valve.

  The brake fluid delivered from the master cylinder instantaneously increases the oil pressure in the vicinity of the master cylinder, but does not increase the wheel cylinder pressure. However, since the hydraulic pressure sensor is provided in the hydraulic pressure actuator near the downstream of the master cylinder, this pressure increase due to the brake fluid is detected, and the detected hydraulic pressure value of the hydraulic pressure sensor increases and the target hydraulic pressure is increased. In some cases, the pressure was exceeded. In this case, the brake ECU receives the detection result of the hydraulic pressure sensor and starts the pressure reduction control of the wheel cylinder pressure. When the hydraulic pressure of the brake fluid delivered from the master cylinder is made uniform and the detected hydraulic pressure value of the hydraulic pressure sensor decreases, the brake ECU increases the wheel cylinder pressure to control the difference from the target hydraulic pressure. Switch to. As described above, in the conventional configuration, since the pressure reduction control is started once and then the pressure increase control is started, the followability of the wheel cylinder pressure with respect to the target hydraulic pressure, that is, the hydraulic pressure responsiveness may be lowered. there were. Since the decrease in the hydraulic pressure response causes the braking distance to be increased, an improvement in the hydraulic pressure response is desired.

  The present invention has been made in view of such circumstances, and an object of the present invention is to provide a technique for improving hydraulic pressure response in a brake control device including an electronically controlled brake.

  In order to solve the above-described problem, a brake control device according to an aspect of the present invention generates a hydraulic pressure in a wheel cylinder by supplying brake fluid through a hydraulic circuit according to an operation of a brake operation member, A brake control device for applying braking force to a wheel by hydraulic pressure, an operation sensor for detecting an operation state of a brake operation member, a hydraulic pressure sensor for detecting a hydraulic pressure of a wheel cylinder, and the operation sensor A control unit for calculating a target hydraulic pressure of the wheel cylinder based on the detection result of the step and adjusting the hydraulic pressure of the wheel cylinder so as to approach the target hydraulic pressure, and the control unit includes: A normal adjustment that adjusts the hydraulic pressure of the wheel cylinder using the detected hydraulic pressure value, and a correction adjustment that adjusts the hydraulic pressure of the wheel cylinder using a correction value obtained by reducing and correcting the detected hydraulic pressure value. Characterized in that it is a feasible and.

  With the brake control device of this aspect, it is possible to improve the hydraulic pressure response in a brake control device including an electronically controlled brake.

  In the above aspect, the control unit may execute the correction adjustment for a predetermined time from the start of the hydraulic pressure adjustment of the wheel cylinder, and perform the normal adjustment after the predetermined time has elapsed. In this case, the hydraulic pressure response of the brake control device can be improved more reliably.

  In the above aspect, a master cylinder connected to the wheel cylinder via a flow path different from the hydraulic circuit, configured to contain the brake fluid and pressurize the brake fluid according to the operation of the brake operation member; A master cut valve provided to be openable and closable in the flow path, and the control unit controls to close the master cut valve in response to a detection result of the operation sensor, and the predetermined time is The time determined based on the time from when the control unit starts the valve closing control of the master cut valve to when the master cut valve is closed may be used. In this case, the control load applied to the control unit can be reduced.

  In the above aspect, the predetermined time may be a time determined based on a timing at which a change in the detected hydraulic pressure value of the hydraulic pressure sensor starts from decreasing to increasing. In this case, the hydraulic pressure response of the brake control device can be further improved.

In the above aspect, the predetermined time may be a time determined based on Equation 1 below.
Predetermined time T1 = (operation sensor response delay time) + (control unit calculation cycle) + (power supply device response time) + (master cut valve coil time constant) + (master cut valve response time) (Equation 1)
In this case, the control load applied to the control unit can be reduced.

  In the above aspect, when the control unit shifts from the correction adjustment to the normal adjustment, the control unit increases the correction value stepwise or continuously to approach the detected hydraulic pressure value, and then shifts to the normal adjustment. You may control to. In this case, it is possible to avoid a sudden change in the wheel cylinder pressure.

  In the above aspect, the operation sensor detects an operation amount of the brake operation member, and the control unit performs the correction adjustment when the operation amount per unit time of the brake operation member exceeds a predetermined threshold value. May be executed. In this case, the control load on the control unit can be reduced while improving the hydraulic pressure response of the brake control device.

  ADVANTAGE OF THE INVENTION According to this invention, the hydraulic-pressure responsiveness in a brake control apparatus provided with the electronically controlled brake can be aimed at.

1 is a schematic configuration diagram of a brake control device according to a first embodiment. It is a figure showing the brake control apparatus which concerns on Embodiment 1, and the electrical structure of the periphery. 3 (A) to 3 (D) are diagrams for explaining adjustment of the wheel cylinder pressure in the conventional brake control device. FIGS. 4A to 4D are diagrams for explaining adjustment of the wheel cylinder pressure in the brake control device according to the first embodiment. 4 is a control flowchart of wheel cylinder pressure in the brake control device according to the first embodiment. It is a figure for demonstrating adjustment of the wheel cylinder pressure in the brake control apparatus which concerns on Embodiment 2. FIG. 6 is a control flowchart of wheel cylinder pressure in the brake control device according to the second embodiment. It is a figure for demonstrating adjustment of the wheel cylinder pressure in the brake control apparatus which concerns on Embodiment 3. FIG. 7 is a control flowchart of wheel cylinder pressure in a brake control device according to a third embodiment. 7 is a control flowchart of wheel cylinder pressure in a brake control device according to a fourth embodiment. It is a schematic block diagram of the brake control apparatus which concerns on a modification.

  Hereinafter, embodiments for carrying out the present invention (hereinafter referred to as embodiments) will be described in detail with reference to the drawings. In the description of the drawings, the same elements are denoted by the same reference numerals, and repeated descriptions are omitted as appropriate.

(Embodiment 1)
FIG. 1 is a schematic configuration diagram of a brake control device according to the first embodiment. The brake control device 100 according to the present embodiment includes a hydraulic brake unit 110 and a brake ECU 200 (control unit) for controlling the operation of each part of the hydraulic brake unit 110. The hydraulic brake unit 110 includes a first piping system that supplies brake fluid to the wheel cylinders for the right front wheel and the left rear wheel, and a second piping that supplies brake fluid to the wheel cylinders for the left front wheel and the right rear wheel. And a so-called X piping structure.

  As shown in FIG. 1, the hydraulic brake unit 110 includes a brake pedal 1 (brake operation member), a stroke sensor 2 (operation sensor), a master cylinder 3, a simulator cut valve SCSS, a stroke simulator 4, and a hydraulic actuator 5. . The hydraulic brake unit 110 is built in brake discs FR, RL, FL, RR provided on the right front wheel, left rear wheel, left front wheel, and right rear wheel (all not shown) of the vehicle, and the brake caliper. And a disc brake unit including wheel cylinders 6FR, 6RL, 6FL, 6RR (hereinafter collectively referred to as “wheel cylinder 6” as appropriate). Each wheel cylinder 6 is connected to the hydraulic actuator 5 via a different brake fluid flow path.

  In each disc brake unit, brake fluid is supplied from the hydraulic actuator 5 to the wheel cylinder 6, and brake pads (not shown) are provided on the brake discs FR, RL, FL, RR that rotate together with each wheel by the hydraulic pressure of the brake fluid. Pressed. Thereby, a braking force is applied to each wheel. In this embodiment, the disc brake unit is used, but other braking force applying mechanisms such as a drum brake may be used.

  When the brake pedal 1 is depressed by the driver, a pedal stroke that is an operation amount of the brake pedal 1 is input to the stroke sensor 2. The stroke sensor 2 transmits a signal indicating the input pedal stroke to the brake ECU 200. Here, the stroke sensor 2 is used as an operation sensor for detecting the operation amount of the brake pedal 1, but a pedal force sensor for detecting the depression force of the brake pedal 1 (the force by which the driver steps on the brake pedal 1) or a master A hydraulic pressure sensor or the like that detects the hydraulic pressure in the cylinder 3 may be used.

  The master cylinder 3 pressurizes the stored brake fluid by operating the brake pedal 1 by the driver, and sends the brake fluid toward the wheel cylinder 6. The master cylinder 3 includes a primary chamber 3a, a secondary chamber 3b, a primary piston 3c, a secondary piston 3d, and a spring 3e.

  The master cylinder 3 is partitioned into a primary chamber 3a and a secondary chamber 3b by a primary piston 3c and a secondary piston 3d. A push rod extending from the brake pedal 1 is connected to the primary piston 3c. The primary piston 3c presses the push rod so as to return the brake pedal 1 to the initial position side when the brake pedal 1 is not depressed due to the elastic force of the spring 3e. The secondary piston 3d also receives the elastic force of the spring 3e and presses the push rod via the primary piston 3c. When the brake pedal 1 is depressed by the driver, the push rod enters the master cylinder 3, and the primary piston 3c and the secondary piston 3d are pressed. Thereby, the stored brake fluid is pressurized, and a master cylinder pressure is generated in the primary chamber 3a and the secondary chamber 3b.

  The primary chamber 3a and the secondary chamber 3b of the master cylinder 3 are connected with a pipeline B and a pipeline A that extend toward the hydraulic actuator 5, respectively.

  The master cylinder 3 is connected to a reservoir tank 3f that stores brake fluid. The reservoir tank 3f is connected to each of the primary chamber 3a and the secondary chamber 3b via a passage (not shown) when the brake pedal 1 is in the initial position, and supplies the brake fluid into the master cylinder 3 or within the master cylinder 3 Of excess brake fluid. A pipeline C and a pipeline D extending toward the hydraulic actuator 5 are connected to the reservoir tank 3f.

  The stroke simulator 4 is connected to a pipeline E connected to the pipeline A, and plays a role of containing brake fluid in the secondary chamber 3 b of the master cylinder 3. A simulator cut valve SCSS is provided in a pipeline E that is a part of a flow path that communicates the master cylinder 3 and the stroke simulator 4. Therefore, the stroke simulator 4 is connected to the pipe line A through the simulator cut valve SCSS. The simulator cut valve SCSS has a solenoid and a spring that are ON / OFF controlled, and is opened by an electromagnetic force generated by the solenoid upon receipt of a specified control current, and the solenoid is in a non-energized state. This is a normally closed electromagnetic control valve that is in a closed state. When the simulator cut valve SCSS is in the closed state, the flow of brake fluid between the pipe line A and the stroke simulator 4 is blocked. When the solenoid is energized and the simulator cut valve SCSS is opened, the brake fluid can be circulated bidirectionally between the stroke simulator 4 and the master cylinder 3. The stroke simulator 4 may be connected to the pipeline B via the pipeline E.

  The stroke simulator 4 includes a plurality of pistons and springs, and creates a reaction force according to the depression force of the brake pedal 1 by the driver when the simulator cut valve SCSS is opened. Specifically, when the brake pedal 1 is depressed with a predetermined depression force, the brake fluid in the secondary chamber 3 b is sent to the stroke simulator 4 via the pipeline A and the pipeline E. When the brake fluid flows into the stroke simulator 4, a hydraulic pressure is generated in the stroke simulator 4, whereby a reaction force is created in the stroke simulator 4. The brake pedal 1 enters the master cylinder 3 until the pedaling force and the reaction force are equal. That is, the stroke stroke of the brake pedal 1 corresponding to the depression force of the brake pedal 1 is created by the stroke simulator 4. As the stroke simulator 4, it is preferable to employ one having multistage spring characteristics in order to improve the feeling of brake operation by the driver.

  The hydraulic actuator 5 includes a pipeline F that connects the secondary chamber 3b of the master cylinder 3 and the wheel cylinder 6FR. One end of the pipe F is connected to the pipe A, the other end is connected to the downstream side of the pump 7 of the individual pipe H1 described later, and a master cut valve SMC1 is provided in the middle. Further, the hydraulic actuator 5 includes a pipeline G that connects the primary chamber 3a of the master cylinder 3 and the wheel cylinder 6FL. One end of the pipe G is connected to the pipe B, the other end is connected to the downstream side of the pump 9 of the individual pipe I3 described later, and a master cut valve SMC2 is provided in the middle.

  The master cut valves SMC1 and SMC2 have solenoids and springs that are ON / OFF controlled, and are closed by electromagnetic force generated by the solenoids when supplied with a prescribed control current, and the solenoids are not energized. The normally open electromagnetic control valve is in a valve open state when When the master cut valves SMC1 and SMC2 are in the open state, the brake fluid is circulated bidirectionally between the master cylinder 3 and the wheel cylinders 6FR and 6FL via the pipelines A and F and the pipelines B and G. Can do. Since the master cut valves SMC1 and SMC2 are normally open electromagnetic control valves, when the brake pedal 1 is not operated, the master cut valves SMC1 and SMC2 are opened and the wheel cylinders are not applied with braking force on the wheels. The hydraulic pressure of 6FR and 6FL can be reliably released. When a prescribed control current is supplied to the solenoid and the master cut valves SMC1, SMC2 are closed, the flow of brake fluid in the pipelines F, G is interrupted. That is, when the master cut valves SMC1, SMC2 are closed, the supply of brake fluid from the master cylinder 3 to the wheel cylinders 6FR, 6FL is shut off.

  The hydraulic actuator 5 includes a pipe H connected to a pipe C extending from the reservoir tank 3f and a pipe I connected to a pipe D similarly extending from the reservoir tank 3f. The pipe H is branched into two pipes called individual pipes H1 and H2. The individual pipe H1 is connected to the wheel cylinder 6FR, and the individual pipe H2 is connected to the wheel cylinder 6RL. The pipe I is branched into two pipes called individual pipes I3 and I4. The individual pipe I3 is connected to the wheel cylinder 6FL, and the individual pipe I4 is connected to the wheel cylinder 6RR.

  Each individual pipe H1, H2, I3, I4 is provided with one pump 7, 8, 9, 10 respectively. Each pump 7-10 is comprised by the trochoid pump excellent in silence, for example. Among the pumps 7 to 10, the pumps 7 and 8 are driven by the first motor 11, and the pumps 9 and 10 are driven by the second motor 12.

  Further, the hydraulic actuator 5 includes pipe lines J1, J2, J3, and J4 arranged in parallel to each of the pumps 7 to 10. A pipe line J1 arranged in parallel with the pump 7 connects the upstream side and the downstream side of the pump 7 so as to bypass the pump 7. In the present embodiment, the pipe J1 has one end connected to the pipe H located on the upstream side of the pump 7 and the other end connected to the pipe F located on the downstream side of the pump 7. Further, a communication valve SRC1 and a hydraulic pressure adjustment valve SLFR are provided in series in the middle of the pipe line J1. The communication valve SRC1 is located downstream of the hydraulic pressure adjustment valve SLFR in the pipeline J1 in the brake fluid flow direction (the suction port side of the pump 7), and the hydraulic pressure adjustment valve SLFR is braked more than the communication valve SRC1 in the pipeline J1. They are respectively arranged on the upstream side (the discharge port side of the pump 7) in the liquid flow direction. A pipe line J <b> 2 arranged in parallel to the pump 8 connects the upstream side and the downstream side of the pump 8, bypassing the pump 8. In the present embodiment, the pipe line J2 has one end connected to the upstream side of the pump 8 of the individual pipe line H2, and the other end connected to the downstream side of the pump 8 of the individual pipe line H2. Further, a hydraulic pressure adjusting valve SLRL is provided in the middle of the pipe line J2.

  The pipe line J3 arranged in parallel to the pump 9 connects the upstream side and the downstream side of the pump 9 so as to bypass the pump 9. In the present embodiment, the pipe line J3 has one end connected to the upstream side of the pump 9 of the individual pipe line I3 and the other end connected to the pipe line G located on the downstream side of the pump 9. A communication valve SRC2 and a hydraulic pressure adjustment valve SLFL are provided in series in the middle of the pipe line J3. The communication valve SRC2 is braked downstream of the hydraulic pressure adjustment valve SLFL in the pipeline J3 in the brake fluid flow direction (the suction port side of the pump 9), and the hydraulic pressure adjustment valve SLFL is braked more than the communication valve SRC2 in the pipeline J3. They are respectively arranged on the upstream side (the discharge port side of the pump 9) in the liquid flow direction. A pipe line J4 arranged in parallel to the pump 10 connects the upstream side and the downstream side of the pump 10 so as to bypass the pump 10. In this embodiment, the pipe line J4 has one end connected to the pipe line I located on the upstream side of the pump 10, and the other end connected to the downstream side of the pump 10 in the individual pipe line I4. A hydraulic pressure adjustment valve SLRR is provided in the middle of the pipe line J4.

  Each of the communication valves SRC1 and SRC2 has a solenoid and a spring that are ON / OFF controlled, both of which are opened by an electromagnetic force generated by the solenoid upon receipt of a specified control current, and the solenoid is not turned on. This is a normally closed electromagnetic control valve that is closed when energized. The communication valves SRC1 and SRC2 that are opened can allow the brake fluid to flow from the wheel cylinders 6FR and 6FL to the reservoir tank 3f. When the solenoid is de-energized and the communication valves SRC1 and SRC2 are closed, the flow of brake fluid in the pipelines J1 and J3 is blocked.

  The hydraulic pressure regulating valves SLFR, SLRL, SLFL, SLRR have a linear solenoid and a spring, and are opened when the linear solenoid is in a non-energized state, and in proportion to the current supplied to the linear solenoid. It is a normally open type electromagnetic control valve in which the opening degree of the valve is adjusted. When the hydraulic pressure adjusting valves SLFR, SLRL, SLFL, and SLRR are in the open state, the brake fluid can be circulated from the wheel cylinder 6 side to the reservoir tank 3f side. When a current is applied to the linear solenoid, the valve is closed in proportion to the supplied current and the flow rate of the brake fluid decreases. Therefore, the flow amount of the brake fluid from each wheel cylinder 6 to the reservoir tank 3f can be changed by changing the opening degree of the hydraulic pressure adjusting valves SLFR, SLRL, SLFL, SLRR. It is possible to adjust the hydraulic pressure generated in

  Wheel cylinder pressure sensors 13, 14, 15, 16 (hydraulic pressure) are located downstream of the pumps 7 to 10 of the individual pipes H 1, H 2, I 3 and I 4 (between the pumps 7 to 10 and the wheel cylinder 6). Sensor). The wheel cylinder pressure sensors 13 to 16 can detect the brake fluid pressure in the wheel cylinders 6FR, 6RL, 6FL, and 6RR, that is, the wheel cylinder pressure. Master cylinder pressure sensors 17 and 18 are provided upstream of the master cut valves SMC1 and SMC2 in the pipelines F and G (between the master cut valves SMC1 and SMC2 and the master cylinder 3). The master cylinder pressure sensors 17 and 18 can detect the hydraulic pressure of the brake fluid in the secondary chamber 3b and the primary chamber 3a of the master cylinder 3, that is, the master cylinder pressure.

  Further, a check valve 20 is provided at the discharge port of the pump 7, and a check valve 21 is provided at the discharge port of the pump 9. The check valves 20 and 21 function to inhibit the flow of brake fluid from the wheel cylinders 6FR and 6FL to the pumps 7 and 9 respectively.

  The hydraulic brake unit 110 configured as described above includes a plurality of piping systems that generate hydraulic pressure in the wheel cylinder 6 by supplying brake fluid via a hydraulic circuit. Specifically, the hydraulic brake unit 110 brakes the reservoir tank 3f to the wheel cylinders 6FR and 6RL via the hydraulic circuit including the pipelines C and H, the individual pipelines H1 and H2, and the pipelines J1 and J2. The brake fluid of the reservoir tank 3f is supplied to the wheel cylinders 6FL and 6RR via a first piping system for supplying the fluid and a hydraulic circuit including the pipelines D and I, the individual pipelines I3 and I4, and the pipelines J3 and J4. A second piping system to be supplied. The first piping system and the second piping system are provided in parallel to the brake fluid supply path from the master cylinder 3 to the wheel cylinder 6. That is, the pumps 7 to 10 are provided in parallel with the master cylinder 3 which is a manual hydraulic pressure source. In the brake control device 100 according to the present embodiment, so-called brake-by-wire braking force control is performed by the first piping system and the second piping system. Further, the hydraulic brake unit 110 is different from the first brake fluid supply path (which is different from the hydraulic circuit) for supplying the brake fluid of the master cylinder 3 which is a manual hydraulic pressure source to the wheel cylinder 6FR via the pipelines A and F. Flow path) and a second brake fluid supply path (flow path different from the hydraulic circuit) that supplies the wheel cylinder 6FL via the pipelines B and G.

  FIG. 2 is a diagram illustrating an electrical configuration of the brake control device according to the first embodiment and its periphery. The brake ECU 200 of the brake control apparatus 100 can hold a CPU that executes various arithmetic processes, a ROM that stores various control programs, a RAM that is used as a work area for data storage and program execution, and stored contents even when the engine is stopped. A non-volatile memory such as a backup RAM, an input / output interface, an A / D converter for converting an analog signal input from various sensors into a digital signal and the like are provided. The brake ECU 200 is connected to a wheel speed sensor 212, a yaw rate sensor 214, a G sensor 216, a rudder angle sensor 218, a voltage detection sensor 220, and the like in order to realize appropriate braking control, and input output signals thereof.

  In addition, a hydraulic brake unit 110 is connected to the brake ECU 200, and output signals from the stroke sensor 2, master cylinder pressure sensors 17 and 18, and wheel cylinder pressure sensors 13, 14, 15, and 16 included in the hydraulic brake unit 110. Is entered. Specifically, a signal indicating the stroke amount of the brake pedal 1 is input from the stroke sensor 2 to the brake ECU 200, and a signal indicating the master cylinder pressure is input from the master cylinder pressure sensors 17, 18, and the wheel cylinder pressure sensor 13 is input. ˜16, a signal indicating the wheel cylinder pressure in the wheel cylinder 6 is input. When a signal is input from the stroke sensor 2, the brake ECU 200 generates the hydraulic pressure in the wheel cylinder 6, and the communication valves SRC 1, SRC 2, the hydraulic pressure adjustment valve included in the hydraulic actuator 5 of the hydraulic brake unit 110. A control current is supplied to SLFR, SLRL, SLFL, SLRR, master cut valves SMC1, SMC2, first motor 11, second motor 12, and the like. Further, the brake ECU 200 supplies a control current to the simulator cut valve SCSS.

  In addition, a hybrid ECU 210 is connected to the brake ECU 200 via a predetermined communication line. The hybrid ECU 210 has the same configuration as the brake ECU 200. The brake ECU 200 acquires information such as a regenerative braking force from the hybrid ECU 210, and calculates the target hydraulic pressure of each wheel cylinder from these information and the stroke amount input from the stroke sensor 2. Then, the brake ECU 200 controls the control valves SRC1, SRC2, the hydraulic pressure adjustment valves SLFR, SLRL, SLFL, SLRR, the first motor 11, the second motor 12, and the like so that each wheel cylinder pressure becomes the target hydraulic pressure. Supply.

  Further, a power supply device 300 is connected to the brake ECU 200. The power supply device 300 includes a main power supply device 302 and an auxiliary power supply device 304. The main power supply device 302 includes a high voltage battery 306 and an auxiliary battery 308 as a main power supply, a DC / DC converter 310, a control circuit (not shown), and the like. The high-voltage battery 306 is a battery for a hybrid vehicle having an output voltage of, for example, 288 V, and supplies electric power to an electric motor (not shown) that drives wheels in a normal traveling state. On the other hand, the auxiliary battery 308 is a battery having an output voltage of, for example, 12 V, and supplies a starting current and a control current necessary for various control units such as the brake ECU 200 and the hybrid ECU 210 and various auxiliary machines such as the hydraulic actuator 5. . The output voltage of the high voltage battery 306 is stepped down to, for example, 12 V by the DC / DC converter 310 and used to charge the auxiliary battery 308.

  The auxiliary power supply device 304 includes a capacitor 312 as an auxiliary power supply, a monitoring circuit 314, a switching circuit 316, and the like. The auxiliary power supply device 304 can store the electric energy supplied from the main power supply device 302 and supply the electric energy to the hydraulic actuator 5 or the like via the brake ECU 200. The capacitor 312 includes a plurality of capacitor cells, and the charge / discharge state is controlled for each cell. The current supplied from the main power supply device 302 is supplied to the capacitor 312 through a power storage circuit including a constant current circuit. Such a capacitor structure and power storage control are well known, and thus detailed description thereof is omitted.

  The monitoring circuit 314 monitors the output voltage of the auxiliary battery 308, and determines the failure of the auxiliary battery 308 or the high voltage battery 306 when the output voltage becomes equal to or lower than the set value. When the monitoring circuit 314 detects the failure of these batteries, the switching circuit 316 switches so that power is supplied from the capacitor 312 to the brake ECU 200, the hydraulic actuator 5, and the like instead of the auxiliary battery 308. The output voltage of auxiliary battery 308 is also detected by voltage detection sensor 220, and the detection information is input to brake ECU 200. Note that the monitoring circuit 314 and the switching circuit 316 may be mounted in the brake ECU 200.

  Next, the brake operation of the brake control device 100 according to the present embodiment will be described with reference to FIG.

  The brake control device 100 executes, for example, brake regeneration cooperative control as a normal braking operation. Specifically, when the brake pedal 1 is depressed and the detection signal of the stroke sensor 2 is input to the brake ECU 200, the brake ECU 200 determines that a braking request has been made and supplies current to the master cut valves SMC1, SMC2. Then, the master cut valves SMC1, SMC2 are closed. The brake ECU 200 opens the simulator cut valve SCSS. As a result, the supply of brake fluid from the master cylinder 3 to the wheel cylinder 6 is cut off, and the brake fluid delivered from the master cylinder 3 is supplied to the stroke simulator 4.

  Also, the brake ECU 200 calculates a required braking force corresponding to the stroke of the brake pedal 1 and subtracts the regenerative braking force from the required braking force to obtain a required hydraulic braking force that is to be generated by the brake control device 100. calculate. Here, the effective value of the braking force by regeneration is supplied from the hybrid ECU 210 to the brake control device 100. Then, the brake ECU 200 calculates the target hydraulic pressure of each wheel cylinder 6 based on the calculated required hydraulic braking force.

  The brake ECU 200 controls the first motor 11 and the second motor 12 to drive the pumps 7 to 10. As a result, the brake fluid stored in the reservoir tank 3f is supplied to the wheel cylinders 6FR and 6RL via the pipelines C and H and the individual pipelines H1 and H2, and the pipelines D and I and the individual pipeline I3. , I4 to the wheel cylinders 6FL, 6RR. When brake fluid is supplied to the wheel cylinders 6 by the pumps 7 to 10, the supplied brake fluid is pressurized and hydraulic pressure is generated in each wheel cylinder 6. Thereby, braking force is given to a wheel. At this time, since the master cut valves SMC1, SMC2 are closed, the brake fluid supplied from the reservoir tank 3f is prevented from returning to the master cylinder 3 via the pipelines F, G.

  The brake ECU 200 opens the communication valves SRC1 and SRC2, and adjusts the opening of the hydraulic pressure adjustment valves SLFR, SLRL, SLFL, and SLRR based on the detection results of the wheel cylinder pressure sensors 13-16. . As a result, the brake fluid supplied to the wheel cylinder 6 returns to the reservoir tank 3f according to the opening of the hydraulic pressure adjustment valves SLFR to SLRR, and feedback adjustment is performed so that the hydraulic pressure in the wheel cylinder 6 becomes the target hydraulic pressure. The Further, the brake ECU 200 controls the drive amount of the pumps 7 to 10 by adjusting the energization amount to the first motor 11 and the second motor 12, thereby increasing / decreasing the amount of each wheel cylinder pressure per unit time (increase / decrease gradient). ). The brake ECU 200 may adjust the hydraulic pressure of each wheel cylinder 6 by adjusting the opening amounts of the hydraulic pressure adjusting valves SLFR to SLRR and controlling the driving amount of the pumps 7 to 10. With the operation described above, the brake control device 100 generates a braking force corresponding to the stroke of the brake pedal 1 on the wheels.

  As described above, the brake control device 100 of the present embodiment operates. Note that the brake control device 100 of the present embodiment has a relationship in which the pedal stroke input of the brake pedal 1 and the supply of brake fluid from the master cylinder 3 to the wheel cylinders 6FR and 6FL are not separated. For this reason, even if some abnormality occurs in the brake control device 100, the brake control device 100 can reliably generate the braking force on the wheels without depending on the control by the brake ECU 200.

  Here, the hydraulic pressure feedback adjustment of the wheel cylinders 6FR and 6FL in the brake control device 100 according to the present embodiment will be described in detail in comparison with the conventional feedback adjustment. Hereinafter, the hydraulic pressure of the wheel cylinders 6FR and 6FL is simply referred to as wheel cylinder pressure.

  3 (A) to 3 (D) are diagrams for explaining adjustment of the wheel cylinder pressure in the conventional brake control device. FIGS. 4A to 4D are diagrams for explaining adjustment of the wheel cylinder pressure in the brake control device according to the first embodiment. FIGS. 3 (A) and 4 (A) show changes over time of the pedal stroke. FIGS. 3 (B) and 4 (B) show the current (SMC) supplied to the master cut valves SMC1 and SMC2. (C) and FIG. 4 (C) show changes with time of wheel cylinder pressure, and FIG. 3 (D) and FIG. 4 (D) show brakes with time. The change with time progress of the adjustment control (ECU control) of the wheel cylinder pressure by ECU200 is shown.

  In the conventional brake control device, when the brake pedal 1 is depressed at the timing of time I shown in FIG. 3 (A) and the pedal stroke a (thick solid line a in FIG. 3 (A)) is detected, the stroke sensor 2 Outputs a detection result signal to the brake ECU 200. When the brake ECU 200 receives the detection result signal from the stroke sensor 2, the brake ECU 200 recognizes that the brake pedal 1 has been operated, and starts adjusting the hydraulic pressure of the wheel cylinder 6 at the timing of time II shown in FIG. .

  Specifically, the brake ECU 200 controls the power supply device 300 to supply current to the master cut valves SMC1, SMC2. When the supply current amount instructed by the brake ECU 200 is the target current b (the thin solid line b in FIG. 3B), the target current b is a predetermined current amount that exceeds the valve closing threshold T at the timing of time II. It becomes. However, the actual current c that is actually supplied to the master cut valves SMC1 and SMC2 (thick solid line c in FIG. 3B) gradually increases, and the timing of time III shown in FIG. 3B. Exceeds the valve closing threshold T. Therefore, the master cut valves SMC1, SMC2 are closed at the timing of time III. Therefore, time X is required from when the brake pedal 1 is operated until the master cut valves SMC1, SMC2 are closed.

  Further, the brake ECU 200 calculates a target hydraulic pressure d (a thin solid line d in FIG. 3C) of the wheel cylinder 6 based on the stroke amount of the brake pedal 1. As the pedal stroke a increases, the target hydraulic pressure d also increases. Then, the brake ECU 200 executes feedback adjustment of the hydraulic pressure of the wheel cylinder 6 using the detected hydraulic pressure value e of the wheel cylinder pressure sensors 13 and 15 (broken line e in FIG. 3C). A thick solid line f in FIG. 3C shows a transition of the operating hydraulic pressure value f used when the brake ECU 200 performs feedback adjustment of the wheel cylinder pressure. In the conventional brake control device, the operating hydraulic pressure value f Is equal to the transition of the detected hydraulic pressure value e of the wheel cylinder pressure sensors 13 and 15.

  Here, as described above, time X is required from when the brake pedal 1 is operated until the master cut valves SMC1, SMC2 are closed. Therefore, a part of the brake fluid pressurized by the master cylinder 3 by depressing the brake pedal 1 flows to the wheel cylinder 6 side during the time X through the first brake fluid supply path and the second brake fluid supply path. May end up. In this case, the increase in the hydraulic pressure due to the flow of the brake fluid is detected by the wheel cylinder pressure sensors 13 and 15, and the detected hydraulic pressure value e of the wheel cylinder pressure sensors 13 and 15 increases. At the timing when the brake ECU 200 starts the feedback adjustment of the wheel cylinder pressure (approximately the timing of time II), the detected hydraulic pressure value e exceeds the target hydraulic pressure d due to this increase, and therefore the operating hydraulic pressure value f becomes the target hydraulic pressure d. It exceeds. Therefore, the brake ECU 200 sets the control content g (thick solid line g in FIG. 3D) to pressure reduction control as shown in FIG.

  The increase in the partial hydraulic pressure in the hydraulic circuit due to the brake fluid flowing from the master cylinder 3 to the wheel cylinder 6 is caused between the hydraulic brake unit 110 and the wheel cylinder 6 before reaching the wheel cylinders 6FR and 6FL ( Damped by hydraulic piping) or absorbed by movement of caliper piston, etc. Therefore, the hydraulic pressure of the brake fluid that flows from the master cylinder 3 to the wheel cylinders 6FR, 6FL gradually decreases, and accordingly, the detected hydraulic pressure value e and the used hydraulic pressure value f gradually decrease. Then, as shown in FIG. 3D, the brake ECU 200 stops the pressure reduction control at the timing of time IV when the difference between the use hydraulic pressure value f and the target hydraulic pressure d becomes a predetermined amount, and the control details g is the hydraulic pressure holding control. Specifically, the hydraulic pressure adjustment valves SLFR and SLFL that have been opened by a predetermined amount are closed. Alternatively, the communication valves SRC1, SRC2 may be closed, and the hydraulic pressure adjustment valves SLFR, SLFL may be opened.

  The increase in the hydraulic pressure detected by the wheel cylinder pressure sensors 13 and 15 is not due to the actual increase in the wheel cylinder pressure. For this reason, even if the hydraulic pressure holding control is performed, the detected hydraulic pressure value e decreases due to the above-described attenuation of the hydraulic pressure, and thus the used hydraulic pressure value f decreases. Then, the brake ECU 200 increases the control content g at the timing of time V when the detected hydraulic pressure value e further decreases and the difference between the used hydraulic pressure value f and the target hydraulic pressure d exceeds a predetermined amount. To do. Until the wheel cylinder pressure starts to be actually increased after switching to the pressure increase control, the detected hydraulic pressure value e continues to decrease due to the above-described equalization of the hydraulic pressure and the like. Thereafter, when the erroneous detection due to the flow of the brake fluid from the master cylinder 3 to the wheel cylinder 6 is resolved, and the detected hydraulic pressure value e starts to increase, the detected hydraulic pressure value e is the actual hydraulic pressure value of the wheel cylinder 6. Is approximately equal.

  As described above, in the conventional brake control device, the wheel cylinder pressure sensor 13 in the initial stage of the control of the wheel cylinder pressure due to the time lag (time X) from the operation of the brake pedal 1 to the closing of the master cut valves SMC1, SMC2. , 15 temporarily increases. Since the brake ECU 200 adjusts the wheel cylinder pressure using such a detected hydraulic pressure value e, the brake ECU 200 performs the pressure reduction control even though the actual wheel cylinder pressure has not increased, and thereafter the hydraulic pressure is increased. The pressure increase control is started through the holding control. Even if the increase in the detected hydraulic pressure value e is not so large as to perform the pressure reduction control, the brake ECU 200 performs the hydraulic pressure holding control and then starts the pressure increase control. Therefore, the time for starting the pressure increase control is delayed. Further, when the pressure increase control is performed after the pressure reduction control is performed, the reactivity of the wheel cylinder pressure with respect to the pressure increase is lowered depending on the response time of each valve. As a result, in the conventional brake control device, a time lag of only time Y occurs between the target hydraulic pressure d and the wheel cylinder pressure (operating hydraulic pressure value f). This time lag corresponds to the followability of the wheel cylinder pressure with respect to the target hydraulic pressure d, that is, the hydraulic pressure response.

  On the other hand, the brake control device 100 according to the present embodiment performs normal adjustment and detection using the detected hydraulic pressure value e of the wheel cylinder pressure sensors 13 and 15 when performing feedback adjustment of the wheel cylinder pressure. A correction adjustment is performed in which the hydraulic pressure value e is adjusted using a correction value obtained by correcting the decrease. Specifically, when the brake pedal 1 is depressed at time I shown in FIG. 4A (thick solid line a in FIG. 4A) and a signal is output from the stroke sensor 2, the brake ECU 200 The hydraulic pressure control of the wheel cylinder 6 is started at the timing of time II shown in FIG.

  As in the case of the conventional brake control device described above, the brake ECU 200 controls the target current b supplied to the master cut valves SMC1, SMC2 so as to exceed the valve closing threshold T (in FIG. 4B). Thin solid line b). As a result, the actual current c (actual current c in FIG. 4B) exceeds the valve closing threshold T at the timing of time III.

  Further, the brake ECU 200 calculates a target hydraulic pressure d of the wheel cylinder 6 (a thin solid line d in FIG. 4C) and performs feedback adjustment of the wheel cylinder pressure. At this time, the brake ECU 200 detects the hydraulic pressure value e detected by the wheel cylinder pressure sensors 13 and 15 as the operating hydraulic pressure value f (thick solid line f in FIG. 4C) for a predetermined time T1 from the start of feedback adjustment. A correction value corrected so as to decrease (broken line e in FIG. 4C) is adopted, and correction adjustment for adjusting the wheel cylinder pressure is performed using this correction value. In the present embodiment, the brake ECU 200 corrects the decrease so that the detected hydraulic pressure value e becomes zero. The reduction correction of the detected hydraulic pressure value e is performed by the brake ECU 200, and the correction value is held in the brake ECU 200. Information about the predetermined time T1 is also held in the brake ECU 200.

  At the timing of time II, the detected hydraulic pressure value e exceeds the target hydraulic pressure d due to the flow of brake fluid from the master cylinder 3 to the wheel cylinders 6FR and 6FL. However, since the brake ECU 200 performs correction adjustment using the correction value, the control content g is at the timing of time VI when the difference between the correction value as the working hydraulic pressure value f and the target hydraulic pressure d exceeds a predetermined amount. (Thick solid line g in FIG. 4D) can be the pressure increase control. Then, after the elapse of the predetermined time T1, the brake ECU 200 switches from the correction adjustment to the normal adjustment using the detected hydraulic pressure value e. The detected hydraulic pressure value e increases due to the flow of brake fluid from the master cylinder 3 and then gradually decreases due to equalization of the hydraulic pressure or the like, but is approximately equal to the actual wheel cylinder pressure when a predetermined time T1 has elapsed. Will be equal. Thereafter, the detected hydraulic pressure value e gradually increases due to the pressure increase control of the brake ECU 200. Note that the brake ECU 200 may perform pressure increase control at the timing of time II when the hydraulic pressure adjustment of the wheel cylinder 6 is started.

  As described above, in the brake control device 100 according to the present embodiment, correction adjustment using the decrease correction value of the detected hydraulic pressure value e is performed for a predetermined time T1 from the start of the hydraulic pressure control. Therefore, the pressure increase control can be started without going through the pressure reduction control and the hydraulic pressure holding control due to the erroneous detection of the wheel cylinder pressure sensors 13 and 15. As a result, the timing at which the hydraulic pressure of the wheel cylinder 6 starts to increase can be made earlier than in the conventional brake control device. As a result, as shown in FIG. 4C, the detected hydraulic pressure value e when the time T1 has elapsed becomes larger than the wheel cylinder pressure f 'in the conventional brake control device at the same time. In the case of the brake control device 100 according to the present embodiment, the time lag (time Z) between the target hydraulic pressure d and the wheel cylinder pressure f (operating hydraulic pressure value f) is set to the target hydraulic pressure d and conventional brake control. It can be made shorter than the time lag (time Y) between the wheel cylinder pressure f ′ (dotted line f ′ in FIG. 4C) in the apparatus.

  Here, the “start of hydraulic pressure adjustment” is, for example, the timing when the brake ECU 200 instructs the power supply device 300 to supply current to the master cut valves SMC1 and SMC2, that is, the timing of time II. Further, the predetermined time T1 is, for example, a time from time II when the brake ECU 200 starts closing control of the master cut valves SMC1 and SMC2 to time III when the master cut valves SMC1 and SMC2 are actually closed, that is, the master cut valve. This time is determined based on the response times of SMC1 and SMC2. In this way, by setting the predetermined time T1 to be a fixed time determined according to the response characteristics of the master cut valves SMC1, SMC2, the control load on the brake ECU 200 can be reduced. In addition to the response time of the master cut valves SMC1 and SMC2, the predetermined time T1 takes into account the time required for the calculation processing by the brake ECU 200, the coil time constant of the master cut valves SMC1 and SMC2, the response time of the power supply device 300, etc. Then, it may be determined based on these elements.

For example, the predetermined time T1 can be expressed by the following formula 1.
T1 = (stroke sensor 2 response delay time) + (brake ECU 200 calculation cycle) + (power supply device 300 response time) + (master cut valves SMC1, SMC2 coil time constant) + (master cut valves SMC1, SMC2 response time) .. (Formula 1)
In this case, since the predetermined time T1 can be uniquely determined, the control load on the brake ECU 200 can be reduced.

  FIG. 5 is a control flowchart of the wheel cylinder pressure in the brake control device according to the first embodiment. This flow is repeatedly executed by the brake ECU 200.

  First, the brake ECU 200 determines whether there is a braking request based on the presence or absence of an output signal from the stroke sensor 2 (S101). When there is no braking request (S101_No), the brake ECU 200 repeats the determination of whether or not there is a braking request. When there is a braking request (S101_Yes), the brake ECU 200 starts adjusting the hydraulic pressure of the wheel cylinder, and performs correction adjustment of the wheel cylinder pressure using the correction value obtained by correcting the decrease in the detected hydraulic pressure value e ( S102). Then, the brake ECU 200 determines whether a predetermined time T1 has elapsed since the start of the hydraulic pressure adjustment (S103). If the predetermined time T1 has not elapsed (S103_No), the brake ECU 200 continues the correction adjustment. On the other hand, when the predetermined time T1 has elapsed (S103_Yes), the brake ECU 200 performs normal adjustment using the detected hydraulic pressure value e (S104) and returns to step 101.

  As described above, the brake control device 100 according to the present embodiment is a brake control device that generates a hydraulic pressure in the wheel cylinder 6 in accordance with the operation of the brake pedal 1 and applies a braking force to the wheels by this hydraulic pressure. Yes, it includes a stroke sensor 2, wheel cylinder pressure sensors 13 to 16, and a brake ECU 200. Then, the brake ECU 200 calculates the target hydraulic pressure of the wheel cylinder 6 based on the detection result of the stroke sensor 2, and adjusts the wheel cylinder pressure to approach the target hydraulic pressure. In the hydraulic pressure adjustment of the wheel cylinders 6FR and 6FL, the brake ECU 200 performs normal adjustment for adjusting the wheel cylinder pressure using the detected hydraulic pressure values of the wheel cylinder pressure sensors 13 and 15, and a correction value for correcting the decrease in the detected hydraulic pressure value. It is possible to carry out correction adjustment to adjust the wheel cylinder pressure using. Therefore, according to the brake control device 100 according to the present embodiment, the brake pedal 1 is depressed, a part of the brake fluid flows from the master cylinder 3 to the wheel cylinder 6 side, and the wheel cylinders by the wheel cylinder pressure sensors 13 and 15 are used. Even when the erroneous detection of the pressure occurs, the wheel cylinder pressure increasing control can be started at an appropriate timing. Thereby, since the hydraulic pressure responsiveness of the brake control apparatus 100 improves, the braking distance of a vehicle can be shortened.

  In the present embodiment, the brake ECU 200 performs correction adjustment for a predetermined time T1 from the start of wheel cylinder pressure adjustment, and performs normal adjustment after the elapse of the predetermined time T1. Thereby, the hydraulic pressure responsiveness of the brake control apparatus 100 can be improved more reliably. The predetermined time T1 is, for example, a time determined based on the time from when the brake ECU 200 starts the valve closing control of the master cut valves SMC1, SMC2 to when the master cut valves SMC1, SMC2 are closed. In this way, by setting the predetermined time T1 to be a fixed time determined according to the response characteristics of the master cut valves SMC1, SMC2, the control load on the brake ECU 200 can be reduced.

(Embodiment 2)
In the brake control device according to the second embodiment, the predetermined time T1 in the brake control device according to the first embodiment is determined based on the timing at which the change in the detected hydraulic pressure value e starts from decreasing to increasing. Hereinafter, this embodiment will be described. Since the main configuration and brake operation of the brake control device are the same as those in the first embodiment, the same components as those in the first embodiment are denoted by the same reference numerals, and the description and illustration thereof are omitted as appropriate. FIG. 6 is a diagram for explaining adjustment of the wheel cylinder pressure in the brake control device according to the second embodiment.

  As described in the first embodiment, since a predetermined time is required from when the brake pedal 1 is depressed until the master cut valves SMC1 and SMC2 are closed, a part of the brake fluid is transferred from the master cylinder 3 to the wheel cylinder 6 side. It will flow. Therefore, as shown in FIG. 6, spike-like increases are seen in the detected hydraulic pressure values e of the wheel cylinder pressure sensors 13 and 15. The magnitude of the spike-like increase varies depending on the amount of brake fluid flowing from the master cylinder 3 to the wheel cylinder 6 side. For example, when the depression speed of the brake pedal 1 is slow and the flow amount of the brake fluid is small, the amount of increase in the detected fluid pressure value e is small, the fluid pressure is equalized, etc., and the detected fluid pressure value e is spiked. The time until the increase converges is relatively short. On the other hand, when the depressing speed of the brake pedal 1 is fast and the flow amount of the brake fluid is large, the amount of increase in the detected fluid pressure value e is large, and the time until the spike-like increase in the detected fluid pressure value e converges. Relatively long.

  Further, when the wheel ECU pressure feedback adjustment is executed by the brake ECU 200, the detected hydraulic pressure value e increases again due to the influence of the pressure increase control after the spike-like increase has converged. Therefore, one minimum point e1 appears in the change in the detected hydraulic pressure value e. The detected hydraulic pressure value e is substantially equal to the actual wheel cylinder pressure in the vicinity of the minimum point e1.

  Therefore, in the brake control device 100 according to the present embodiment, the change in the detected hydraulic pressure value e is increased from the decrease during the predetermined time T1, which is the time for performing correction adjustment using the decreased correction value of the detected hydraulic pressure value e. The time was determined based on the turning timing. Specifically, the brake ECU 200 receives the detected hydraulic pressure value e from the wheel cylinder pressure sensors 13 and 15, and compares the received detected hydraulic pressure value e with the previously received detected hydraulic pressure value e. Then, the brake ECU 200 determines that the predetermined time T1 has elapsed when the first detection hydraulic pressure value e larger than the previous detection hydraulic pressure value e is received after detecting the decrease in the detection hydraulic pressure value e. . The brake ECU 200 that has determined that the predetermined time T1 has elapsed switches the correction adjustment to the normal adjustment. Accordingly, the time for executing the correction adjustment can be changed according to the magnitude of the increase in the detected hydraulic pressure value e caused by the flow of the brake fluid from the master cylinder 3, so that the hydraulic response of the brake control device 100 can be changed. The sex can be further improved.

  FIG. 7 is a flowchart of wheel cylinder pressure control in the brake control device according to the second embodiment. This flow is repeatedly executed by the brake ECU 200.

  First, the brake ECU 200 determines whether there is a braking request based on the presence or absence of an output signal from the stroke sensor 2 (S201). When there is no braking request (S201_No), the brake ECU 200 repeats the determination of whether or not there is a braking request. When there is a braking request (S201_Yes), the brake ECU 200 starts the hydraulic pressure adjustment, and performs the correction adjustment of the wheel cylinder pressure using the correction value obtained by correcting the decrease in the detected hydraulic pressure value e (S202). Then, the brake ECU 200 determines whether the change in the detected hydraulic pressure value e has changed from a decrease to an increase (S203). If the change in the detected hydraulic pressure value e has not changed from a decrease to an increase (S203_No), the brake ECU 200 determines that the predetermined time T1 has not elapsed and continues the correction adjustment. On the other hand, when the change in the detected hydraulic pressure value e starts from decreasing to increasing (S203_Yes), the brake ECU 200 determines that the predetermined time T1 has elapsed, and performs normal adjustment using the detected hydraulic pressure value e ( S204), the process returns to step 201.

  As described above, in the brake control device 100 according to the present embodiment, the predetermined time T1 is determined based on the timing at which the change in the detected hydraulic pressure value e starts from decreasing to increasing. Therefore, although the control burden applied to the brake ECU 200 increases as compared with the first embodiment, the hydraulic pressure response of the brake control device 100 can be further improved. Further, immediately after the detected hydraulic pressure value e reaches the minimum point e1, the operating hydraulic pressure value f is switched from the correction value to the detected hydraulic pressure value e, so that the change amount of the operating hydraulic pressure value f accompanying the switching is reduced. can do. Thereby, since it is possible to avoid a sudden change in the wheel cylinder pressure, it is possible to suppress the occurrence of pulsation, and as a result, it is possible to prevent the generation of abnormal noise.

(Embodiment 3)
The brake control device according to the third embodiment performs control in the brake control device according to the second embodiment to gradually increase the correction value to approach the detected hydraulic pressure value e when shifting from the correction adjustment to the normal adjustment. Is. Hereinafter, this embodiment will be described. Since the main configuration and brake operation of the brake control device are the same as those in the second embodiment, the same components as those in the second embodiment are denoted by the same reference numerals, and the description and illustration thereof are omitted as appropriate. FIG. 8 is a diagram for explaining adjustment of the wheel cylinder pressure in the brake control device according to the third embodiment.

  In the present embodiment, as shown in FIG. 8, when the correction adjustment is switched to the normal adjustment after a predetermined time T1 has elapsed, the correction value as the working fluid pressure value f is increased stepwise or continuously to detect the detection liquid. After approaching the pressure value e, the working fluid pressure value f is switched from the correction value to the detected fluid pressure value e. Specifically, for example, when the predetermined time T1 elapses, the brake ECU 200 sets a value obtained by adding 1/2 of the difference between the correction value and the detected hydraulic pressure value e to the correction value as a new use hydraulic pressure value f. And the working fluid pressure value f is gradually brought closer to the detected fluid pressure value e. As a result, the amount of change in the working fluid pressure value f that accompanies the switching from the correction adjustment to the normal adjustment can be further reduced, so that the occurrence of pulsation can be suppressed more reliably, and therefore the generation of abnormal noise can be performed more reliably. Can be prevented.

  FIG. 9 is a flowchart of wheel cylinder pressure control in the brake control device according to the third embodiment. This flow is repeatedly executed by the brake ECU 200.

  First, the brake ECU 200 determines whether there is a braking request based on the presence or absence of an output signal from the stroke sensor 2 (S301). When there is no braking request (S301_No), the brake ECU 200 repeats the determination of whether or not there is a braking request. When there is a braking request (S301_Yes), the brake ECU 200 performs correction adjustment of the wheel cylinder pressure using the correction value obtained by correcting the decrease in the detected hydraulic pressure value e (S302). Then, the brake ECU 200 determines whether the change in the detected hydraulic pressure value e has changed from a decrease to an increase (S303). If the change in the detected hydraulic pressure value e has not changed from a decrease to an increase (S303_No), the brake ECU 200 continues the correction adjustment. On the other hand, when the change in the detected hydraulic pressure value e starts from decreasing to increasing (S303_Yes), the brake ECU 200 gradually increases the correction value as the used hydraulic pressure value f (S304), and then detects the detected hydraulic pressure value e. (S305), the process returns to step 301.

  As described above, in the brake control device 100 according to the present embodiment, when the correction adjustment is switched to the normal adjustment after the predetermined time T1 has elapsed, the correction value as the working hydraulic pressure value f is changed stepwise or continuously. After increasing the pressure to approach the detection fluid pressure value e, the control is shifted to normal adjustment. Therefore, an improvement effect of the hydraulic pressure response of the brake control device 100 can be obtained, and the occurrence of pulsation can be suppressed more reliably, and therefore the generation of abnormal noise can be more reliably prevented.

(Embodiment 4)
The brake control device according to the fourth embodiment switches execution / non-execution of correction adjustment in accordance with the depression speed of the brake pedal 1 in the brake control device according to the third embodiment. Hereinafter, this embodiment will be described. Since the main configuration and brake operation of the brake control device are the same as those in the third embodiment, the same components as those in the third embodiment are denoted by the same reference numerals, and the description and illustration thereof are omitted as appropriate.

  As described in the second embodiment, the magnitude of the spike-like increase seen in the detected hydraulic pressure value e of the wheel cylinder pressure sensors 13 and 15 is the amount of brake fluid flowing from the master cylinder 3 to the wheel cylinder 6 side, etc. It changes according to. When the depression speed of the brake pedal 1 is very slow and the flow amount of the brake fluid is very small, the spike-like increase in the detected hydraulic pressure value e is negligibly small. In this case, the minimum point e1 of the change in the detected hydraulic pressure value e may not be detected, and the predetermined time T1 may not be determined.

  Therefore, in the present embodiment, it is determined whether or not correction adjustment is performed according to the depression speed of the brake pedal 1. Specifically, the brake ECU 200 calculates a stroke amount per unit time when the brake pedal 1 is depressed and a signal is output from the stroke sensor 2. The brake ECU 200 executes correction adjustment when the stroke amount per unit time exceeds a predetermined threshold value, and performs correction adjustment when the stroke amount per unit time is equal to or less than the predetermined threshold value. Perform normal adjustments without performing them. As a result, only normal adjustment can be executed when correction adjustment is not necessary, so that the control burden on the brake ECU 200 can be reduced. Further, it is possible to avoid a situation where the predetermined time T1 cannot be determined.

  FIG. 10 is a control flowchart of the wheel cylinder pressure in the brake control device according to the fourth embodiment. This flow is repeatedly executed by the brake ECU 200.

  First, the brake ECU 200 determines whether there is a braking request based on the presence or absence of an output signal from the stroke sensor 2 (S401). When there is no braking request (S401_No), the brake ECU 200 repeats the determination of whether or not there is a braking request. When there is a braking request (S401_Yes), the brake ECU 200 determines whether the stroke amount per unit time of the brake pedal 1 exceeds a threshold value (S402). When the stroke amount per unit time is equal to or less than the threshold value (S402_No), the brake ECU 200 executes normal adjustment (S406).

  When the stroke amount per unit time is higher than the threshold value (S402_Yes), the brake ECU 200 performs correction adjustment of the wheel cylinder pressure using the correction value obtained by correcting and decreasing the detected hydraulic pressure value e (S403). ). Then, the brake ECU 200 determines whether the change in the detected hydraulic pressure value e has changed from a decrease to an increase (S404). If the change in the detected hydraulic pressure value e has not changed from a decrease to an increase (S404_No), the brake ECU 200 continues the correction adjustment. On the other hand, when the change in the detected hydraulic pressure value e starts from decreasing to increasing (S404_Yes), the brake ECU 200 gradually increases the correction value as the operating hydraulic pressure value f (S405), and then detects the detected hydraulic pressure value e. The normal adjustment using is performed (S406), and the process returns to step 401.

  As described above, in the brake control device 100 according to the present embodiment, correction adjustment is performed when the stroke amount per unit time of the brake pedal 1 exceeds a predetermined threshold value. Therefore, it is possible to reduce the control burden on the brake ECU 200 while improving the hydraulic pressure response of the brake control device 100. In addition, it is possible to more accurately detect the timing for switching the correction adjustment to the normal adjustment.

  The present invention is not limited to the above-described embodiment, and an appropriate combination of the elements of each embodiment is also effective as an embodiment of the present invention. Various modifications such as design changes can be added to the embodiments based on the knowledge of those skilled in the art, and such combined or modified embodiments are also included in the scope of the present invention. Can be. A new embodiment generated by the combination of the above-described embodiments and the addition of a modification has the effects of the combined embodiment and the added modification. The configuration shown in each figure is for explaining an example, and any configuration that can achieve the same function can be changed as appropriate, and the same effect can be obtained.

  For example, in the above-described third embodiment, the unique configuration is added to the second embodiment, and in the fourth embodiment, the unique configuration is added to the third embodiment. The configuration may be added to the first embodiment, and the specific configuration of the fourth embodiment may be added to the first and second embodiments.

(Modification)
For example, the brake control device 100 may include the following hydraulic circuit, and even in this case, the control of the above-described first to fourth embodiments can be applied. Can play. FIG. 11 is a schematic configuration diagram of a brake control device according to a modification.
In addition, the same code | symbol is attached | subjected about the structure similar to Embodiment 1, and the description and illustration are abbreviate | omitted suitably.

  As shown in FIG. 11, the brake control device 100 includes a hydraulic brake unit 110 and a brake ECU 200. The hydraulic brake unit 110 includes a brake pedal 1, a stroke sensor 2, a master cylinder 3, a simulator cut valve SCSS, a stroke simulator 4, and a hydraulic actuator 400. The hydraulic brake unit 110 includes a disc brake unit including brake discs FR, FL, RR, RL and wheel cylinders 6FR, 6FL, 6RR, 6RL built in the brake caliper.

  One end of a brake fluid pressure control pipe 402 for the right front wheel is connected to the secondary chamber 3 b of the master cylinder 3. The other end of the brake fluid pressure control pipe 402 is connected to the wheel cylinder 6FR. One end of a brake fluid pressure control pipe 404 for the left front wheel is connected to the primary chamber 3a of the master cylinder 3. The other end of the brake fluid pressure control pipe 404 is connected to the wheel cylinder 6FL. A master cut valve SMC1 and a master cylinder pressure sensor 17 are provided in the middle of the brake fluid pressure control pipe 402, and a master cut valve SMC2 and a master cylinder pressure sensor 18 are provided in the middle of the brake fluid pressure control pipe 404. It has been.

  On the other hand, one end of a hydraulic pressure supply / discharge pipe 406 is connected to the reservoir tank 3f, and the suction port of an oil pump 410 driven by a motor 408 is connected to the other end of the hydraulic pressure supply / discharge pipe 406. ing. The discharge port of the oil pump 410 is connected to a high-pressure pipe 412, and an accumulator 414 and a relief valve 416 as a pressure accumulating portion of a hydraulic pressure source are connected to the high-pressure pipe 412. In this modification, a reciprocating pump having two or more pistons (not shown) that are reciprocally moved by a motor 408 is employed as the oil pump 410. As the accumulator 414, an accumulator 414 that converts the pressure energy of the brake fluid into pressure energy of an enclosed gas such as nitrogen is stored.

  The accumulator 414 normally stores the brake fluid that has been pressurized to a predetermined hydraulic pressure range (for example, about 14 to 21 MPa) by the oil pump 410. Further, the valve outlet of the relief valve 416 is connected to a hydraulic pressure supply / discharge pipe 406. When the pressure of the brake fluid in the accumulator 414 increases abnormally to, for example, about 25 MPa, the relief valve 416 is opened, The brake fluid is returned to the hydraulic pressure supply / discharge pipe 406. Further, the high-pressure pipe 412 is provided with an accumulator pressure sensor 415 that detects the outlet pressure of the accumulator 414, that is, the pressure of the brake fluid in the accumulator 414.

  The high-pressure pipe 412 is connected to the wheel cylinders 6FR, 6FL, 6RR, 6RL via pressure increase valves 418FR, 418FL, 418RR, 418RL (hereinafter collectively referred to as “pressure increase valve 418” as appropriate). Each booster valve 418 has a linear solenoid and a spring, and is closed when the linear solenoid is in a non-energized state. The valve opening is adjusted in proportion to the current supplied to the linear solenoid. Is a normally closed electromagnetic control valve. The pressure increasing valve 418 can increase the pressure of the wheel cylinder 6 according to the opening degree.

  Further, the wheel cylinders 6FR and 6FL are connected to a hydraulic pressure supply / discharge pipe 406 via a pressure reducing valve 420FR or 420FL, respectively. The pressure reducing valves 420FR and 420FL have a linear solenoid and a spring, and are normally closed electromagnetic control valves capable of reducing the pressure of the wheel cylinders 6FR and 6FL according to their opening degrees. On the other hand, the wheel cylinders 6RR and 6RL are connected to a hydraulic pressure supply / discharge pipe 406 via a pressure reducing valve 420RR or 420RL which is a normally open electromagnetic control valve. Hereinafter, the pressure reducing valves 420FR to 420RL are collectively referred to as “pressure reducing valve 420” as appropriate. Wheel cylinder pressure sensors 13 and 15 are provided in the vicinity of the wheel cylinders 6FR and 6FL, and wheel cylinder pressure sensors 16 and 14 are provided in the vicinity of the wheel cylinders 6RR and 6RL.

  The brake ECU 200 is electrically connected to master cut valves SMC1, SMC2, simulator cut valve SCSS, pressure increasing valve 418, pressure reducing valve 420, motor 408, and the like. The brake ECU 200 receives signals from the wheel cylinder pressure sensors 13 to 16, the stroke sensor 2, the master cylinder pressure sensors 17 and 18, and the accumulator pressure sensor 415.

  The brake control device 100 configured as described above can execute brake regeneration cooperative control. The brake control device 100 receives a braking request and calculates a required braking force and a required hydraulic braking force. The brake ECU 200 calculates the target hydraulic pressure of each wheel cylinder 6 based on the calculated required hydraulic braking force, and supplies it to the pressure increasing valve 418 and the pressure reducing valve 420 by a feedback control law so that the wheel cylinder pressure becomes the target hydraulic pressure. The value of the control current to be determined is determined. As a result, in the brake control device 100, brake fluid is supplied from the accumulator 414 to each wheel cylinder 6 via each pressure increasing valve 418, and braking force is applied to the wheels. Further, brake fluid is discharged from each wheel cylinder 6 through the pressure reducing valve 420 as necessary, and the braking force applied to the wheel is adjusted.

  On the other hand, at this time, master cut valves SMC1 and SMC2 are closed, and simulator cut valve SCSS is opened. Therefore, the brake fluid sent from the master cylinder 3 when the driver depresses the brake pedal 1 flows into the stroke simulator 4 through the simulator cut valve SCSS. Further, when the accumulator pressure is equal to or lower than the lower limit value of the preset setting range, current is supplied to the motor 408 by the brake ECU 200, and the oil pump 410 is driven to increase the accumulator pressure. When the accumulator pressure enters the set range and reaches the upper limit value due to this pressure increase, power supply to the motor 408 is stopped.

  SMC1, SMC2 Master cut valve, 2 stroke sensor, 3 master cylinder, 5 hydraulic actuator, 6, 6FL, 6FR, 6RL, 6RR wheel cylinder, 13, 14, 15, 16 wheel cylinder pressure sensor, 100 brake control device, 110 Hydraulic brake unit, 200 brake ECU.

Claims (6)

A brake control device that generates a hydraulic pressure in a wheel cylinder by supplying brake fluid through a hydraulic circuit according to an operation of a brake operation member, and applies a braking force to the wheel by the hydraulic pressure,
An operation sensor for detecting an operation state of the brake operation member;
A hydraulic pressure sensor for detecting the hydraulic pressure of the wheel cylinder;
A control unit for calculating a target hydraulic pressure of the wheel cylinder based on a detection result of the operation sensor and adjusting the hydraulic pressure of the wheel cylinder so as to approach the target hydraulic pressure; and
The control unit adjusts the hydraulic pressure of the wheel cylinder using a normal adjustment for adjusting the hydraulic pressure of the wheel cylinder using the detected hydraulic pressure value of the hydraulic pressure sensor and a correction value obtained by correcting the decrease of the detected hydraulic pressure value. Ri executable der the correction adjusting to a predetermined time from the start of the liquid-pressure control of the wheel cylinder, performs the correction adjusting, after a predetermined time, brake characterized that you run the normal regulation Control device. A master cylinder connected to the wheel cylinder through a flow path different from the hydraulic circuit, configured to contain the brake fluid and pressurize the brake fluid according to the operation of the brake operation member;
A master cut valve provided in the flow path to be openable and closable,
The control unit receives the detection result of the operation sensor and controls to close the master cut valve,
2. The brake control device according to claim 1 , wherein the predetermined time is a time determined based on a time from when the control unit starts closing control of the master cut valve to when the master cut valve is closed. 2. The brake control device according to claim 1 , wherein the predetermined time is a time determined based on a timing at which a change in the hydraulic pressure value detected by the hydraulic pressure sensor changes from a decrease to an increase. The brake control device according to claim 2 , wherein the predetermined time is a time determined based on Formula 1 below.
Predetermined time = (operation sensor response delay time) + (control unit calculation cycle) + (power supply device response time) + (master cut valve coil time constant) + (master cut valve response time) (Equation 1) The control unit, when shifting from the correction adjustment to the normal adjustment, controls to shift to the normal adjustment after increasing the correction value stepwise or continuously to approach the detected hydraulic pressure value. Item 5. The brake control device according to any one of items 1 to 4 . The operation sensor detects an operation amount of a brake operation member,
Wherein, when the operation amount per unit time of the brake operating member has exceeded a predetermined threshold, the brake control device according to any one of claims 1 to 5 to perform the correction adjustment.

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