JP5948982B2 - Brake control device for vehicle - Google Patents

Description

  In the present invention, an M / C pressure is generated in a master cylinder (hereinafter referred to as M / C) in response to depression of a brake pedal, and a wheel cylinder (hereinafter referred to as W / C) is added based on the M / C pressure. The present invention relates to a vehicle brake control device that controls the brake fluid pressure in the hydraulic brake device.

  Conventionally, the M / C pressure generated by depressing the brake pedal and the brake pressurization by the brake hydraulic pressure pressurizing means for sucking and pressurizing the brake fluid from the M / C are supplied to the W / C. There is a brake mechanism that pressurizes the W / C pressure to be higher than the M / C pressure (see, for example, Patent Document 1). In this brake mechanism, the pressurization amount is increased according to the stroke amount during the invalid stroke from when the brake pedal is depressed until the port of the master reservoir provided in the M / C is closed, and after the port is closed, the pressure is increased. While maintaining the pressure amount as it is, control is performed such that the W / C pressure increases and the braking force increases as the M / C pressure increases.

JP 2006-21745 A

  However, even if the master reservoir port is closed and brake fluid is supplied from the M / C, the brake fluid is consumed to fill the empty decompression reservoir first. As a result, the W / C pressure does not increase. For this reason, the generated deceleration is stagnated without increasing, giving the driver a sense of incongruity that the deceleration corresponding to the depression of the brake pedal is not obtained, which may worsen the brake feeling. is there.

  SUMMARY OF THE INVENTION In view of the above, the present invention provides a vehicle brake control device that can suppress a deceleration from decelerating when a port of a master reservoir is closed and prevent deterioration in brake feeling. With the goal.

In order to achieve the above object, in the invention described in claim 1, the brake fluid pressure pressurizing means includes a pipe line (A) connecting M / C (13) and W / C (14, 15, 34, 35). , E) and a differential pressure control valve (16, 36) that forms a differential pressure between the M / C pressure and the W / C pressure, and a differential pressure by the differential pressure control valve (16, 36). The pump (19, 39) pressurizes the W / C pressure by sucking out the brake fluid in the M / C (13) in a state of providing the pressure and discharging it to the W / C (14, 15, 34, 35). And a motor (60) for driving the pump, and pipes (C, D, G, H) connecting the M / C (13) and the suction side of the pump (19, 39). Control means (70) for outputting a differential pressure instruction value which is a value indicating the differential pressure formed by the reservoir (20, 40) and the differential pressure control valve (16, 36). It is configured to include and. Then, M / C (13) during the operation start of the brake operation member (11) of a predetermined stroke, has an invalid stroke M / C pressure is not generated, the control means (70), the master Pressure extension stroke setting means (105) for setting a pressure extension stroke that continues to increase the differential pressure command value to the differential pressure control valve until the cylinder (13) stroke becomes equal to or greater than the invalid stroke. During the invalid stroke, the differential pressure indication value to the differential pressure control valve (16, 36) is changed so that the braking force corresponding to the stroke amount of M / C (13) is generated. In response to the stroke amount of M / C (13) by changing the differential pressure command value to the differential pressure control valve (16, 36) during the set pressure extension stroke even after the invalid stroke. Brake force Is characterized by pressurizing the W / C pressure by a pump (19, 39) so as to.

  Thus, even if the pressurization extension stroke is set and the stroke of M / C (13) exceeds the invalid stroke, the differential pressure command value to the differential pressure control valve (16, 36) is further applied during the pressurization extension stroke. Is continuously increased so that the pressurization of the W / C pressure by the pump (19, 39) can be continued. Accordingly, the brake fluid can be supplied to the W / C side while the reservoirs (20, 40) are filled with the brake fluid, and the W / C pressure can be continuously increased. . Therefore, it is possible to suppress the deceleration from decelerating when the port (13f) of the master reservoir (13e) is closed, and to prevent the brake feeling from deteriorating.

  In the second aspect of the invention, the differential pressure indication value is based on an increase amount of the differential pressure generated by the differential pressure control valve (16, 36) with respect to the stroke of M / C (13) during the pressurization extension stroke. The brake fluid amount required with the increasing W / C pressure is set to be smaller than the brake fluid amount supplied by the stroke of M / C (13).

  As a result, even if the differential pressure command value to the differential pressure control valve (16, 36) is continuously increased, the M / C (13) exceeds the amount of liquid consumed in the undercarriage corresponding to the differential pressure increase amount. Brake fluid can be supplied. For this reason, the inside of the reservoir (20, 40) can be reliably filled with the brake fluid.

  In the invention according to claim 3, when the stroke of the M / C (13) is larger than the pressurization extension stroke, the control means (70) provides the differential pressure instruction value to the differential pressure control valve (16, 36). It is characterized by holding.

  Thereby, after the stroke of M / C (13) becomes larger than the pressurization extension stroke, it becomes possible to increase the W / C pressure by the increase of the M / C pressure corresponding to the brake operation amount. .

  In the invention according to claim 4, the pressurization extension stroke setting means (105) sets the pressurization extension stroke smaller when the change speed of the stroke of M / C (13) is high than when it is low. It is a feature.

  As the change speed of the M / C stroke increases, the M / C pressure may be generated due to the orifice effect due to the smaller opening area of the port (13f) of the master piston (13a, 13b). In such a case, since the M / C pressure is generated earlier, the pressurization extension stroke may be shortened. Therefore, it is preferable to make the pressurization extension stroke smaller when the change speed of the M / C stroke is faster than when it is lower than that.

  In addition, the code | symbol in the bracket | parenthesis of each said means shows the correspondence with the specific means as described in embodiment mentioned later.

It is the figure which showed the block structure of each function of the hybrid vehicle by which the vehicle braking control apparatus 1 to which 1st Embodiment of this invention was applied is mounted. It is the figure which showed the detailed structure of each part which comprises a hydraulic brake device. It is sectional drawing which showed the mode in M / C13 according to the depression state of the brake pedal 11. FIG. It is the figure which showed the depression of the brake pedal 11, and the relationship between each parameter. It is sectional drawing which showed operation | movement of the pressure regulation reservoirs 20 and 40 according to the state in M / C13. It is the figure which showed the relationship between the M / C stroke shown in FIG.4 (b), the vehicle deceleration, and the differential pressure instruction | indication value. It is sectional drawing which showed the mode of the cup seal 13g when M / C pressure has generate | occur | produced and when M / C pressure became negative pressure by sucking out brake fluid. 3 is a flowchart showing details of a braking control process executed by the vehicle braking control device 1; It is the figure which showed the change of each parameter when the pressurization extension stroke is not set. It is the figure which showed the change of each parameter at the time of setting a pressurization extension stroke.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. In the following embodiments, the same or equivalent parts are denoted by the same reference numerals in the drawings.

(First embodiment)
A first embodiment of the present invention will be described. FIG. 1 shows a block configuration of each function of a hybrid vehicle equipped with a vehicle braking control apparatus 1 to which the first embodiment of the present invention is applied.

  First, the hydraulic brake device in the vehicle brake control device 1 of the present embodiment will be described. As shown in FIG. 1, the vehicle brake control device 1 includes a brake pedal 11, a booster device 12, an M / C 13, W / C 14, 15, 34, 35, and an actuator for brake fluid pressure control. 50, and these constitute a hydraulic brake device. The vehicle brake control device 1 is provided with a brake ECU 70. The brake ECU 70 functions as part of a control unit that executes cooperative control of the hydraulic brake device and a regenerative brake device described later, so that the hydraulic braking force generated by the hydraulic brake device and the regenerative control generated by the regenerative brake device are performed. Control power. FIG. 2 is a diagram showing a detailed structure of each part constituting the hydraulic brake device.

  As shown in FIG. 2, a stroke sensor 11 a is connected to a brake pedal 11 as a brake operation member that is depressed by a driver, and a detection signal from the stroke sensor 11 a is transmitted to the brake ECU 70. 11, the amount of depression, that is, the amount of brake operation can be detected. The brake pedal 11 is connected to a booster 12 and an M / C 13 that are brake fluid pressure generation sources. When the driver steps on the brake pedal 11, the booster 12 boosts the pedaling force, and M / Master pistons 13a and 13b arranged at C13 are pressed. Thereby, the M / C pressure of the same pressure according to the brake operation amount of the driver is generated in the primary chamber 13c and the secondary chamber 13d defined by the master pistons 13a and 13b.

  The M / C 13 is provided with a master reservoir 13e having passages communicating with the primary chamber 13c and the secondary chamber 13d. The master reservoir 13e supplies brake fluid into the M / C 13 through the passage, or stores excess brake fluid in the M / C 13. The M / C pressure generated in the M / C 13 is transmitted to each W / C 14, 15, 34, 35 through the brake fluid pressure control actuator 50.

  The brake fluid pressure control actuator 50 includes a first piping system 50a and a second piping system 50b. The first piping system 50a controls the brake fluid pressure applied to the left front wheel FL and the right rear wheel RR, and the second piping system 50b controls the brake fluid pressure applied to the left rear wheel RL and the right front wheel FR. X piping is constituted by these two piping systems of the first and second piping systems 50a, 50b.

  Hereinafter, the first and second piping systems 50a and 50b will be described. However, since the first piping system 50a and the second piping system 50b have substantially the same configuration, the first piping system 50a will be described here. For the second piping system 50b, refer to the first piping system 50a.

  The first piping system 50a includes a pipeline A serving as a main pipeline that transmits the above-described M / C pressure to the W / C 14 provided on the left front wheel FL and the W / C 15 provided on the right rear wheel RR. ing. Through this line A, W / C pressure is generated in each of the W / Cs 14 and 15.

  Further, the pipe line A is provided with a first differential pressure control valve 16 including a pressure regulating valve that can be controlled between a communication state and a differential pressure state. The first differential pressure control valve 16 is in a communicating state in the normal brake state, and is in a differential pressure state when a current is passed through the solenoid. The differential pressure formed by the first differential pressure control valve 16 changes according to the current value of the current flowing through the solenoid, and the larger the current value, the larger the differential pressure amount. When the first differential pressure control valve 16 is in the differential pressure state, the flow of the brake fluid is regulated so that the W / C pressure is higher than the M / C pressure by the amount of the differential pressure.

  The pipe A branches into two pipes A1 and A2 downstream of the first differential pressure control valve 16 on the W / C 14 and 15 side. One of the two pipes A1 and A2 is provided with a first pressure increase control valve 17 for controlling the increase of the brake fluid pressure to the W / C 14, and the other is an increase of the brake fluid pressure to the W / C 15. A second pressure increase control valve 18 is provided for controlling the pressure.

  The first and second pressure increase control valves 17 and 18 are configured as electromagnetic valves as two-position valves that can control the communication / blocking state. When the first and second pressure-increasing control valves 17 and 18 are controlled to be in a communicating state, the M / C pressure or the brake fluid pressure due to the discharge of brake fluid from a pump 19 described later is applied to the W / C 14 and 15. .

  During normal braking by the driver operating the brake pedal 11, the first differential pressure control valve 16 and the first and second pressure increase control valves 17 and 18 are constantly controlled. The first differential pressure control valve 16 and the first and second pressure increase control valves 17 and 18 are provided with safety valves 16a, 17a and 18a, respectively, in parallel.

  In the pipeline A, the first and second pressure-increasing control valves 17 and 18 and the pipeline B serving as a pressure-reducing pipeline connecting between the W / Cs 14 and 15 and the pressure regulating reservoir 20 are controlled in the communication / blocking state. As a two-position valve that can be formed, a first pressure reduction control valve 21 and a second pressure reduction control valve 22 each comprising an electromagnetic valve are provided. These first and second pressure reducing control valves 21 and 22 are always cut off during normal braking.

  A conduit C serving as a reflux conduit is disposed so as to connect between the pressure regulating reservoir 20 and the conduit A serving as the main conduit. This pipe C is provided with a self-priming pump 19 driven by a motor 60 so as to suck and discharge brake fluid from the pressure regulating reservoir 20 toward the M / C 13 side or the W / C 14, 15 side. Yes. The discharge port side of the pump 19 is provided with a safety valve 19a so that high-pressure brake fluid is not applied to the pump 19, and a fixed capacity for relaxing the pulsation of the brake fluid discharged by the pump 19. A damper 23 is provided.

  And the pipe line D used as an auxiliary pipe line is provided so that the pressure regulation reservoir 20 and M / C13 may be connected. The brake fluid is sucked from the M / C 13 by the pump 19 through the pipe D and discharged to the pipe A, so that the W / W can be used during TCS (Traction Control System) control or BA (Brake Assist) control. Brake fluid is supplied to the C14, 15 side so that the W / C pressure of the target wheel can be increased.

  The pressure adjustment reservoir 20 is connected to the pipe D and receives the brake fluid from the M / C 13 side. The reservoir hole 20a is connected to the pipe B and the pipe C, and the brake fluid discharged from the W / Cs 14 and 15 is discharged. A reservoir hole 20b for receiving and supplying brake fluid to the suction side of the pump 19 is provided and communicates with the reservoir chamber 20c. A valve body 20d made of a ball valve or the like is disposed inside the reservoir hole 20a. The valve body 20d is attached to and detached from the valve seat 20e to control the communication interruption between the pipe D and the reservoir chamber 20c, and the distance between the valve seat 20e and the reservoir chamber 20c is adjusted. The pressure difference between the internal pressure and the M / C pressure is regulated. Below the valve body 20d, a rod 20f having a predetermined stroke for moving the valve body 20d up and down is provided separately from the valve body 20d. Also, in the reservoir chamber 20c, there are a piston 20g interlocking with the rod 20f, and a spring 20h that generates a force for pressing the piston 20g toward the valve body 20d to push out the brake fluid in the reservoir chamber 20c. Is provided.

  The pressure regulating reservoir 20 configured as described above is configured such that when a predetermined amount of brake fluid is stored, the valve body 20d is seated on the valve seat 20e and the brake fluid does not flow into the pressure regulating reservoir 20. . Therefore, more brake fluid than the suction capacity of the pump 19 does not flow into the reservoir chamber 20c, and no high pressure is applied to the suction side of the pump 19.

  The brake fluid pressure control actuator 50 is provided with an M / C pressure sensor 51. The M / C pressure sensor 51 is provided in a portion of the brake pipe that has the same pressure as the M / C pressure. In the present embodiment, the M / C pressure sensor 51 and the first differential pressure in the pipe A A control valve 16 is provided. A detection signal of the M / C pressure sensor 51 is transmitted to the brake ECU 70.

  On the other hand, as described above, the second piping system 50b has substantially the same configuration as the first piping system 50a. That is, the first differential pressure control valve 16 and the safety valve 16a correspond to the second differential pressure control valve 36 and the safety valve 36a. The first and second pressure increase control valves 17 and 18 and the safety valves 17a and 18a correspond to the third and fourth pressure increase control valves 37 and 38 and the safety valves 37a and 38a, respectively. , 22 correspond to the third and fourth decompression control valves 41, 42, respectively. The pressure regulating reservoir 20 and the components 20a to 20h correspond to the pressure regulating reservoir 40 and the components 40a to 40h. The pump 19 and the safety valve 19a correspond to the pump 39 and the safety valve 39a. The damper 23 corresponds to the damper 43. Further, the pipeline A, the pipeline B, the pipeline C, and the pipeline D correspond to the pipeline E, the pipeline F, the pipeline G, and the pipeline H, respectively. As described above, the hydraulic brake device in the vehicle brake control device 1 is configured. In the hydraulic brake device having such a configuration, the first and second differential pressure control valves 16 and 36, the pumps 19 and 39, the pressure regulating reservoirs 20 and 40, and the motor 60 are used to provide the brake hydraulic pressure pressurizing means in the present invention. Is configured.

  The brake ECU 70 is configured by a known microcomputer including a CPU, a ROM, a RAM, an I / O, and the like, and executes processing such as various calculations according to a program stored in the ROM. For example, the brake ECU 70 obtains the stroke amount or M / C pressure of the brake pedal 11 from the detection signal of the stroke sensor 11a or the detection signal of the M / C pressure sensor 51, or the target braking force corresponding to the stroke amount of the brake pedal 11. Or an electric signal is output to the brake fluid pressure control actuator 50 in order to pressurize the pump. Based on the electric signal from the brake ECU 70, voltage application control to the motors 60 for driving the control valves 16-18, 21, 22, 36-38, 41, 42 and the pumps 19, 39 is executed. Thereby, control of the W / C pressure generated in each W / C 14, 15, 34, 35 is performed.

  Specifically, in the brake hydraulic pressure control actuator 50, when current is supplied from the brake ECU 70 to the motor 60 and the solenoid for driving the control valve, the control valves 16 to 18, 21 are controlled according to the current supply. , 22, 36 to 38, 41, 42 are driven, and the route of the brake piping is set. Then, the brake fluid pressure corresponding to the set brake piping path is generated in the W / Cs 14, 15, 34, and 35, and the braking force generated in each wheel is controlled.

  For example, when the hydraulic pressure braking force is generated by pressurizing the front wheels FL and FR so that the W / C pressure at the W / C 14 and 34 is higher than the M / C pressure, the second differential pressure control valve 16 and the second differential pressure control valve 16 The motor 60 is driven in a state where the pressure control valve 36 is in the differential pressure state, and the pumps 19 and 39 perform the brake fluid suction / discharge operation. As a result, the brake fluid in the M / C 13 is sucked into the pump 19 through the pipelines D and C, and supplied to the W / C 14 of the front wheel FL through the pipelines C and A. Similarly, the brake fluid in the M / C 13 is sucked into the pump 39 through the pipelines H and G, and is supplied to the W / C 34 of the front wheel FR through the pipelines G and E. At this time, since the differential pressure is generated between the M / C 13 and the W / C 14, 34 by the pressure regulating valves in the first differential pressure control valve 16 and the second differential pressure control valve 36, the W / C 14, 34 becomes M The pressure is increased to a W / C pressure higher than the / C pressure, and a hydraulic braking force is generated.

  As shown in FIG. 1, the hybrid vehicle includes a regenerative brake device 80 and a hybrid ECU 81 that controls the regenerative brake device 80 to perform regenerative brake control.

  The regenerative brake device 80 includes a motor connected to an axle that connects both front wheels FL and FR, an inverter electrically connected to the motor, a battery electrically connected to the inverter, and the like. . The motor is configured, for example, as an AC synchronous type, and power is supplied to the motor by converting a DC current generated by the battery in the inverter into an AC current. The inverter plays a role of converting a direct current of the battery into an alternating current based on a control signal of the hybrid ECU 81, or a role of charging the battery by converting an alternating current generated by the motor into a direct current.

  The hybrid ECU 81 mainly controls the drive system. The hybrid ECU 81 supplies data used for regenerative brake control to the brake ECU 70, and conversely receives necessary data from the brake ECU 70.

  The hybrid ECU 81 performs regenerative brake control and the like in cooperation with the brake ECU 70, controls the inverter, and controls the operation of the motor. That is, the operation of the motor is controlled by an inverter based on the control signal of the hybrid ECU 81, and the motor is driven by the rotational force of both front wheels FL and FR (or the axle connecting them) to generate electric power. Charge the battery. Since the braking force is generated by the resistance force of the motor during the power generation, this is used as the regenerative braking force.

  At this time, the hybrid ECU 81 handles various information of the regenerative braking device 80 and transmits necessary information to the brake ECU 70 in response to a request from the brake ECU 70. The various information handled by the hybrid ECU 81 here is information such as a regenerative braking force amount, a regenerative braking force gradient, and a regenerative execution braking force. The regenerative braking force amount means the maximum value of the regenerative braking force generated by the regenerative braking device 80. Further, the regenerative braking force gradient means a gradient of the regenerative braking force that can be generated by the regenerative braking device 80 in this control cycle. The regenerative execution braking force is a regenerative braking force actually generated by the regenerative braking device 80. The regenerative braking force and the regenerative braking force gradient are values determined from the capability of the regenerative braking device 80. The hybrid ECU 81 calculates the regenerative braking force that can be actually requested from the regenerative braking force amount and the regenerative braking force gradient. Then, the regenerative braking force is generated based on the regenerative braking force that can be requested, and the actually generated regenerative execution braking force is obtained and transmitted to the brake ECU 70. For example, the regeneration execution braking force is obtained as follows. That is, since the regenerative execution torque corresponding to the regenerative braking force can be obtained from the back electromotive force generated by the motor, the regenerative execution torque corresponding to the regenerative braking force is obtained from the back electromotive force of the motor obtained by a known method. Ask. The regeneration execution braking force is obtained by further converting the regeneration execution torque or the regeneration execution torque into a braking force.

  Next, the operation of the vehicle brake control device 1 configured as described above will be described. First, prior to description of a specific operation of the vehicle brake control device 1, the reason for performing the operation will be described.

  When braking is started, a hydraulic braking force is generated by the hydraulic brake device in order to generate a target braking force corresponding to the stroke amount of the brake pedal 11 detected based on the detection signal of the stroke sensor 11a, and the regeneration is performed. A regenerative braking force is generated by the brake device 80. The cooperative control of the hydraulic brake device and the regenerative brake device 80 is performed so that the total braking force of the hydraulic braking force and the regenerative braking force becomes the target braking force.

  At this time, in the hydraulic brake device, there is an invalid stroke in which no M / C pressure is generated until the brake pedal 11 is depressed by a predetermined amount or more. And the first and second differential pressure control valves 16 and 36 are set in a differential pressure state to start pump pressurization.

  FIG. 3 is a cross-sectional view showing the inside of the M / C 13 according to the depression state of the brake pedal 11. FIG. 4 shows the stroke values of the M / C pistons 13a and 13b (hereinafter referred to as M / C strokes) based on the depression of the brake pedal 11 and the indication values of the differential pressure amounts at the first and second differential pressure control valves 16 and 36. It is a figure showing the relation between vehicle deceleration (hereinafter referred to as differential pressure command value), and M / C pressure. FIG. 5 is a cross-sectional view showing the operation of the pressure regulating reservoirs 20 and 40 according to the state in the M / C 13. In FIG. 3, for the sake of simplification, the M / C 13 is composed of only the primary chamber 13c, but the same operation is performed in the secondary chamber 13d as in the primary chamber 13c.

  As shown in FIG. 3A, the primary chamber 13c and the master reservoir 13e communicate with each other at the initial depression of the brake pedal 11, specifically until the port 13f of the master piston 13a reaches the cup seal 13g. Yes. For this reason, even if the brake pedal 11 is depressed, the stroke becomes an invalid stroke in which the M / C pressure does not increase. At this time, the brake fluid in the M / C 13 is sucked out by the pumps 19 and 39 and supplied to the W / C 14, 15, 34, and 35 sides. Thereby, the W / C pressure can be increased even during the invalid stroke. At this time, since the primary chamber 13c and the master reservoir 13e communicate with each other, the brake fluid is supplied from the master reservoir 13e even if the brake fluid in the M / C 13 is sucked, and the M / C pressure is zero. It becomes a state.

  In order to increase the W / C pressure, the first and second differential pressure control valves 16 and 36 are in a differential pressure state. Since the M / C pressure is in a zero state, the differential pressure component is W / C pressure. For this reason, the first and second differential pressure control valves 16, so that the braking force component to be generated as the hydraulic braking force is generated by subtracting the regenerative braking force generated by the regenerative braking device 80 from the target braking force. A differential pressure command value 36 is set, and a current corresponding to the differential pressure command value is supplied to the first and second differential pressure control valves 16 and 36.

  When the brake pedal 11 is depressed by the invalid stroke, thereafter, the M / C pressure is generated according to the depression of the brake pedal 11. That is, as shown in FIG. 3B, when the brake pedal 11 is depressed by an amount corresponding to the invalid stroke, the port 13f of the master piston 13a reaches the cup seal 13g, and the master reservoir 13e and the primary chamber 13c are shut off. . Therefore, when the brake pedal 11 is depressed thereafter, the brake fluid is supplied to the pumps 19 and 39 only from within the M / C 13 as shown in FIG. Thus, the M / C pressure is generated.

  Therefore, conventionally, as shown by a solid line in FIG. 4A, when the M / C stroke becomes the stroke amount A, that is, the port 13f is closed, the primary chamber 13c, the secondary chamber 13d, the master reservoir 13e, The differential pressure instruction value when the engine is shut off is held, and the W / C pressure is increased by the increase in the M / C pressure according to the depression of the brake pedal 11.

  At this time, ideally, even if the differential pressure command value when the M / C stroke reaches the stroke amount A is held, the M / C pressure increases, and the braking force and deceleration continuously increase. It should be. However, actually, before the M / C stroke reaches the stroke amount A, the pressure in the vicinity of the pressure regulating reservoirs 20 and 40 is 0 or slightly negative, as shown in FIG. The brake fluid in the reservoir chambers 20c, 40c of the pressure regulating reservoirs 20, 40 is almost empty, and the pistons 20g, 40g in the pressure regulating reservoirs 20, 40 are located above the valve bodies 20d, 40d and the valve The suction opening area formed by the seats 20e, 40e is also wide. Therefore, when the pressure in the vicinity of the pressure regulating reservoirs 20 and 40 changes to a positive pressure by closing the port 13f and applying the M / C pressure, the pistons in the pressure regulating reservoirs 20 and 40 as shown in FIG. As shown in FIG. 5 (c), the suction opening area formed by the valve bodies 20d, 40d and the valve seats 20e, 40e is narrowed by the strokes of the pistons 20g, 40g. A pressure regulation state in which the differential pressure between the internal pressures of the chambers 20c and 40c and the M / C pressure is regulated, and the M / C pressure increases. As described above, after the pressure in the vicinity of the pressure regulating reservoirs 20 and 40 is changed to a positive pressure, the pistons 20g and 40g in the pressure regulating reservoirs 20 and 40 with a large suction opening area as shown in FIG. Strokes downward, and the state where the amount of brake fluid is taken as the amount of fluid consumption occurs, so that the M / C pressure increases even when the stroke amount A is reached, as shown by the solid line in FIG. Since the brake fluid is not supplied to the W / C side, the W / C pressure does not increase, and the vehicle deceleration stays at a substantially constant value as shown in FIG. 4B. In particular, the springs 20h and 40h in the pressure regulating reservoirs 20 and 40 are set to a very low reaction force in consideration of pressure reduction of the W / C pressure on a low μ road having a low road surface friction coefficient μ. When pressure is applied, the strokes of the pistons 20g and 40g are easily allowed to cause the above phenomenon.

  In order to improve this, the first and second differential pressures are set so that the pressurization by the pumps 19 and 39 rises in the meantime in anticipation of changes in the strokes of the pistons 20g and 40g in the pressure regulating reservoirs 20 and 40. The differential pressure command value of the control valves 16 and 36 is increased. For example, as indicated by a broken line in FIG. 4A, the differential pressure instruction value corresponding to the stroke amount of the brake pedal 11 is not generated when the M / C stroke becomes the stroke amount A, but the pressure adjustment reservoir It is generated when the stroke amount B takes into account the strokes of the pistons 20g, 40g in the 20, 40.

  In this way, even after the M / C stroke reaches the stroke amount A, the differential pressure instruction value continues to increase and the pressurization by the pumps 19 and 39 is continued. As a result, the M / C pressure also increases continuously, and since the brake fluid is supplied to the W / C side, the W / C pressure also increases. Therefore, it is possible to suppress the deceleration from being delayed when the port 13f of the master reservoir 13e is closed, and it is possible to continuously increase the deceleration. For this reason, it becomes possible to prevent the deterioration of the brake feeling that the deceleration cannot be obtained even when the brake pedal 11 is depressed.

  In this way, considering the amount of liquid consumed in the pressure regulating reservoirs 20 and 40, the differential pressure instruction value is continuously increased until the stroke amount B is reached after the M / C stroke becomes the stroke amount A. That is, the pressurization extension stroke is set so as to extend the M / C stroke in which the pump pressurization amount is increased. By providing such a pressurization extension stroke, the above-mentioned effect can be obtained. However, if the amount of liquid consumption around the undercarriage increases due to the increase in the differential pressure instruction value, that is, the increase in the differential pressure, the pressure is adjusted. The reservoirs 20 and 40 cannot be filled with the brake fluid. This will be described with reference to FIG.

  FIG. 6 is a diagram showing the relationship between the M / C stroke and the vehicle deceleration shown in FIG. 4B and the differential pressure command value. Conventionally, as indicated by the solid line in the figure, since the differential pressure command value is held when the stroke amount exceeds the invalid stroke, the vehicle deceleration is stagnant and the pressure adjusting reservoirs 20 and 40 are filled with the brake fluid. After that, the vehicle deceleration increased again. For this reason, in the present embodiment, as shown by the broken line in the figure, even if the stroke amount is not less than the invalid stroke, the pressure extension indicated value is continuously increased by providing the pressure extension stroke, and the pump The amount of pressurization is continuously raised.

  Since no M / C pressure is generated during the invalid stroke, the W / C pressure is generated by the differential pressure generated by the first and second differential pressure control valves 16 and 36. At this time, the brake fluid of the amount corresponding to the W / C pressure generated by the differential pressure is supplied from the M / C 13 to the underbody (that is, each W / C).

  Thereafter, during the pressurization extension stroke, the M / C 13 responds to the differential pressures by the first and second differential pressure control valves 16 and 36 until a predetermined amount of pressure regulation is accumulated in the pressure regulation reservoirs 20 and 40. Thus, the amount of brake fluid supplied to the W / C 14, 15, 34, 35 and the amount of fluid to fill the pressure regulating reservoirs 20, 40 are supplied. At this time, if the amount of increase in the differential pressure in the first and second differential pressure control valves 16 and 36 is large and the amount of liquid consumed in the underbody (that is, each W / C) increases, the inside of the pressure regulating reservoirs 20 and 40 is increased. It cannot be filled with brake fluid.

  For this reason, the amount of increase in the differential pressure in the first and second differential pressure control valves 16, 36 is based on the M / C 13 based on the M / C stroke. It is set to be smaller than the amount of brake fluid supplied. As a result, even if the differential pressure instruction value to the first and second differential pressure control valves 16 and 36 is continuously increased, the M / C 13 exceeds the amount of liquid consumption in the undercarriage corresponding to the increased differential pressure. Since the brake fluid can be supplied, the pressure regulating reservoirs 20 and 40 can be reliably filled with the brake fluid.

  Even if the amount of increase in the differential pressure at the first and second differential pressure control valves 16 and 36 is large and the amount of liquid consumed in the undercarriage increases, the action of the cup seal 13g in the M / C 13 Brake fluid is supplied from the back of the cup seal 13g. FIG. 7 is a cross-sectional view showing the state of the cup seal 13g when the M / C pressure is generated and when the M / C pressure becomes negative due to the suction of the brake fluid. As shown in FIG. 7A, when the M / C pressure is generated, the M / C pressure is applied to the cup seal 13g, so that the seal is sealed by the cup seal 13g, and the M / C 13 is sealed from the master reservoir 13e. Brake fluid is not supplied inside. Therefore, at this time, the brake fluid in the M / C 13 is sucked out. On the other hand, as shown in FIG. 7B, when the M / C pressure becomes negative, the cup seal 13g cannot be sealed, and the brake fluid is supplied from the master reservoir 13e through the back surface of the cup seal 13g. For this reason, even if the amount of increase in the differential pressure at the first and second differential pressure control valves 16, 36 is large and the amount of liquid consumed in the undercarriage increases, brake fluid is supplied from the back of the cup seal 13g, It does not become less than the amount of liquid consumed in the undercarriage.

  When the pressure adjusting reservoirs 20 and 40 are filled with a predetermined amount of brake fluid that is in a pressure adjusting state and the stroke amount of the M / C stroke is further increased than the pressure extension stroke, the first and second differential pressures are increased. The differential pressure instruction value to the control valves 16 and 36 is held. At this time, the amount of liquid consumed on the upstream side (M / C side) of the first and second differential pressure control valves 16 and 36 required for increasing the M / C pressure, and the first and second differential pressure control valves 16 , 36 is supplied from the M / C 13 in accordance with the W / C pressure generated on the downstream side (W / C side) based on the differential pressure. The brake fluid is supplied to the downstream side of the first and second differential pressure control valves 16 and 36 from the upstream side through the first and second differential pressure control valves 16 and 36, and the pumps 19 and 39. In any case, the relationship between the M / C stroke and the W / C pressure is the same as that of the normal brake.

  Thus, in this embodiment, even if the M / C stroke becomes equal to or greater than the invalid stroke, the differential pressure command values of the first and second differential pressure control valves 16 and 36 are continuously increased and the pressure by the pumps 19 and 39 is increased. To continue. As a result, the M / C pressure increases continuously and the W / C pressure also increases during the pressurization extension stroke, and the deceleration of the deceleration is suppressed when the port 13f of the master reservoir 13e is closed. It can be so.

  Next, the operation of the vehicle brake control device 1 when the pressure extension stroke is provided as described above will be described. FIG. 8 is a flowchart showing details of the braking control process executed by the vehicle braking control device 1. The process shown in this figure is executed in the brake ECU 70 at every predetermined control cycle.

  First, in step 100, input processing is performed. Specifically, the detection signal of the stroke sensor 11a and the detection signal of the M / C pressure sensor 51 are input, and the M / C stroke, that is, the stroke amount of the M / C pistons 13a and 13b is calculated based on this detection signal. . The detection signal of the stroke sensor 11a is a signal corresponding to the stroke amount of the brake pedal 11, that is, the brake operation amount, and the stroke amount of the brake pedal 11 is a value corresponding to the M / C stroke. Therefore, the M / C stroke can be calculated based on the detection signal of the stroke sensor 11a. Further, the M / C pressure is detected based on the detection signal of the M / C pressure sensor 51.

  In the following step 105, based on the M / C stroke calculated in step 100, the target braking force to be generated corresponding to the M / C stroke is calculated, and then the control is performed by subtracting the M / C pressure from the target braking force. Calculate the braking force.

  The target braking force is a value determined according to the brake operation amount so as to increase as the brake operation amount increases. In general, the target braking force is obtained from a function equation or a map representing the relationship between the brake operation amount and the target braking force. Can do. Here, since the calculated brake operation amount is a value corresponding to the M / C stroke, the target braking force is calculated based on the M / C stroke. Further, the control braking force is a value obtained by subtracting the M / C pressure from the target braking force, that is, a hydraulic braking force by pump pressurization that is a braking force generated other than the M / C pressure in the target braking force, and a regenerative braking device. The braking force corresponding to the regenerative braking force of 80. As described above, since brake fluid is consumed in the pressure adjusting reservoirs 20 and 40, no M / C pressure is generated during the pressurization extension stroke even if the M / C stroke exceeds the invalid stroke. For this reason, in this embodiment, the pressurization extension stroke is set in advance as a constant value, and the pressurization extension stroke for the control braking force even if the M / C stroke exceeds the invalid stroke and further reaches the pressurization extension stroke. During this period, the value increases continuously. When the M / C pressure is generated, the control braking force is maintained at a constant value thereafter.

  Then, the process proceeds to step 110, where the regenerative request braking force is transmitted to the hybrid ECU 81. Here, since the regenerative braking device 80 is desired to generate as much regenerative braking force as possible, the braking braking force is transmitted to the hybrid ECU 81 as a regenerative request braking force. Further, in step 115, information transmitted from the hybrid ECU 81, specifically, information related to the regenerative execution braking force generated by the regenerative braking device 80 is received. Based on this, in step 120, the regenerative braking force is calculated. That is, the regenerative execution braking force is the regenerative braking force actually generated at that time, and this is set as the regenerative braking force.

  In step 125, the pump pressurization amount is calculated. The pump pressurization amount is a hydraulic braking force generated by pump pressurization, and is a value obtained by subtracting the regenerative braking force from the control braking force. The control braking force is a braking force corresponding to a hydraulic braking force due to pump pressurization and a regenerative braking force by the regenerative braking device 80, which is a braking force generated other than the M / C pressure among the target braking force. For this reason, if the regenerative braking force generated by the regenerative braking device 80 is subtracted from the control braking force, the hydraulic braking force (= pump pressurization amount) by pump pressurization is obtained. In consideration of the consumption of brake fluid in the pressure regulating reservoirs 20 and 40 when the port 13f is closed as described above, even if the M / C stroke exceeds the invalid stroke, control is further performed during the pressure extension stroke. The braking force is a value that continuously increases. For this reason, the pump pressurization amount also becomes a value that continuously increases until the M / C stroke reaches the pressurization extension stroke.

  After this, the routine proceeds to step 130, where the current value corresponding to the differential pressure command value to the first and second differential pressure control valves 16, 36, that is, the differential pressure amount of the first and second differential pressure control valves 16, 36 is determined. The current value output to the first and second differential pressure control valves 16 and 36 is calculated to control the value according to the differential pressure command value. In addition, since the differential pressure instruction value to the first and second differential pressure control valves 16 and 36 corresponds to the pump pressurization amount, this calculation is performed based on the calculation result in step 125. Thereafter, in step 135, the current of the current value calculated in step 130 is output to the first and second differential pressure control valves 16, 36, and the first pump pressure is generated in order to generate the calculated pump pressurization amount. The differential pressure amount of the second differential pressure control valves 16 and 36 is controlled to be a value according to the differential pressure command value.

  As described above, the pressure extension stroke is set, and even if the M / C stroke exceeds the invalid stroke, the differential pressure command value to the first and second differential pressure control valves 16 and 36 is further applied during the pressure extension stroke. Is continuously raised so that pump pressurization can be continued. Thus, the brake fluid can be supplied to the W / C side while the pressure regulating reservoirs 20 and 40 are filled with the brake fluid, and the W / C pressure can be continuously increased. . Therefore, it is possible to prevent the deceleration from deteriorating when the port 13f of the master reservoir 13e is closed, and to prevent the brake feeling from deteriorating.

  For reference, FIGS. 9 and 10 show changes in parameters when the pressure extension stroke is not set and when it is set. As shown in FIG. 9, when the pressure extension stroke is not set, the differential pressure instruction value is held when the M / C stroke is equal to or greater than the invalid stroke and the port 13f is closed. For this reason, in period T1, it turns out that deceleration is substantially constant and stagnates until the inside of pressure regulation reservoirs 20 and 40 is filled up with brake fluid. On the other hand, as shown in FIG. 10, when the pressure extension stroke is set, the differential pressure command value continuously increases even if the M / C stroke exceeds the invalid stroke and further reaches the pressure extension stroke. Be made. For this reason, the W / C pressure can be increased while filling the pressure regulating reservoirs 20 and 40 with the brake fluid, so that the deceleration can be continuously increased without stagnation.

(Other embodiments)
In the above-described embodiment, the vehicle brake control device that performs the emphasis control between the hydraulic brake device and the regenerative brake device 80 has been described. However, the brake fluid is sucked out from the M / C 13 and the W / C pressure is higher than the M / C pressure. The present invention can be applied to a vehicular braking control device that performs brake control to pressurize the pump so that the pressure increases.

In the above embodiment, it is assumed that the pressurization extension stroke is a constant value, but the pressurization extension stroke may be set according to the changing speed of the M / C stroke. That is, the faster the change speed of the M / C stroke, the M / C pressure may be generated due to the orifice effect due to the smaller opening area of the port 13f of the master piston 13a, 13b. In such a case, since the M / C pressure is generated earlier, the pressurization extension stroke may be shortened. Therefore, it is preferable to make the pressurization extension stroke smaller when the change speed of the M / C stroke is faster than when it is lower than that. In this case, the pressure extension stroke may be calculated and set according to the change rate of the M / C stroke instead of using a preset value in step 105 of FIG. The portion to run the process in step 105 functions as a pressure roll length stroke setting means in substantially present invention.

  Moreover, in the said embodiment, although it has set as the form that a differential pressure instruction | indication value increases with a fixed gradient with respect to the increase in M / C stroke, it does not necessarily need to be such a form. For example, the differential pressure command value may increase exponentially as the M / C stroke increases, or the gradient may change midway.

  Moreover, in the said embodiment, the brake pedal 11 is mentioned as an example and demonstrated as a brake operation member. However, other brake operation members such as a brake lever may be used. In the above embodiment, the regenerative braking force is applied only to the right front wheel FR and the left front wheel FL. However, the regenerative braking force may be applied to the rear wheels or all the wheels. The vehicle may not have regenerative braking force. Further, in the present embodiment, the brake piping type is configured as an X piping in which the right front wheel FR and the left rear wheel RL are of the same system and the left front wheel FL and the right rear wheel RR of the same system, but the right front wheel FR and the left front wheel are configured. It is good also as a structure of the front-and-back piping which makes FL the same system and the right rear wheel RR and the left rear wheel RL have the same system. Moreover, although the pressure regulation reservoirs 20 and 40 are used as the reservoirs provided on the suction port side of the pumps 19 and 39, a general reservoir without a pressure regulation valve may be used.

   DESCRIPTION OF SYMBOLS 1 ... Vehicle brake control apparatus, 11 ... Brake pedal, 11a ... Stroke sensor, 12 ... Booster, 13 ... M / C, 14, 15, 34, 35 ... W / C, 16, 36 ... Differential pressure control valve , 19, 39 ... pump, 50 ... brake hydraulic pressure control actuator, 51 ... M / C pressure sensor, 60 ... motor, 70 ... brake ECU, 80 ... regenerative brake device, 81 ... hybrid ECU

Claims (4)

A master cylinder (13) that generates a master cylinder pressure by a stroke of a built-in piston (13a, 13b) based on a brake operation amount when the driver operates a brake operation member (11);
A wheel cylinder (14, 15, 34, 35) that generates a hydraulic braking force for each wheel (FL to RR) by applying a wheel cylinder pressure based on the master cylinder pressure;
Brake fluid pressure pressurizing means (16, 36, 19, 20, 39, 40, 60) for pressurizing the wheel cylinder pressure so that the wheel cylinder pressure is higher than the master cylinder pressure. Control the hydraulic brake device
Fluid pressure control based on wheel cylinder pressure applied to the wheel cylinder (14, 15, 34, 35) using the brake fluid pressure pressurizing means (16, 36, 19, 20, 39, 40, 60). In the vehicle brake control device for generating a target braking force corresponding to the operation amount of the brake operation member (11) by generating power,
The brake fluid pressure pressurizing means is
A differential pressure between the master cylinder pressure and the wheel cylinder pressure is provided in the middle of pipes (A, E) connecting the master cylinder (13) and the wheel cylinders (14, 15, 34, 35). A differential pressure control valve (16, 36) forming
With the differential pressure provided by the differential pressure control valve (16, 36), the brake fluid in the master cylinder (13) is sucked out and discharged toward the wheel cylinder (14, 15, 34, 35). A pump (19, 39) for pressurizing the wheel cylinder pressure by:
A motor (60) for driving the pump;
Reservoirs (20, 40) provided in the middle of pipelines (C, D, G, H) connecting the master cylinder (13) and the suction side of the pumps (19, 39);
Control means (70) for outputting a differential pressure instruction value that is a value indicating the differential pressure formed by the differential pressure control valve (16, 36),
The master cylinder (13) has an invalid stroke in which the master cylinder pressure is not generated for a predetermined stroke amount from the start of operation of the brake operation member (11),
The control means (70) is a pressurizing extension stroke that continues to increase the differential pressure command value to the differential pressure control valve until the predetermined stroke is reached after the stroke of the master cylinder (13) becomes equal to or greater than the invalid stroke. A pressure extension stroke setting means (105) for setting the differential pressure control valve (16, 36) so as to generate a braking force according to the stroke amount of the master cylinder (13) during the invalid stroke. ) To control the differential pressure by changing the differential pressure indication value to the differential pressure control valve (16, 36) during the set pressure extension stroke even after the invalid stroke. The wheel cylinder pressure is increased by the pump (19, 39) so as to generate a braking force corresponding to the stroke amount of the master cylinder (13) by changing the indicated value. Vehicle, characterized in Rukoto brake controller.   The wheel cylinder increases based on the amount of increase in the differential pressure generated by the differential pressure control valve (16, 36) with respect to the stroke of the master cylinder (13) during the pressurization extension stroke. The brake control device for a vehicle according to claim 1, characterized in that the amount of brake fluid required with pressure is set to be smaller than the amount of brake fluid supplied by the stroke of the master cylinder (13). .   When the stroke of the master cylinder (13) is larger than the pressurization extension stroke, the control means (70) holds a differential pressure instruction value to the differential pressure control valve (16, 36). The vehicle brake control device according to claim 1.   The pressurization extension stroke setting means (105) sets the pressurization extension stroke smaller when the change speed of the stroke of the master cylinder (13) is high than when it is low. 4. The vehicle brake control device according to any one of 3 above.

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