JP6626758B2 - Vehicle brake fluid pressure control device - Google Patents

Description

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

  Conventionally, as a vehicle brake fluid pressure control device, a volume of the brake fluid stored in a reservoir for storing the brake fluid is estimated, and based on the volume, a pump output sufficient to empty the reservoir (reservoir). A method of calculating a discharge amount of brake fluid from a vehicle (see Patent Document 1) is known.

JP 2001-505505 A

  By the way, in the case of a pump using an eccentric cam, the calculated discharge amount and the actual protrusion amount may vary depending on the rotational position of the eccentric cam. It may not be possible to fully return to the source side.

  Therefore, an object of the present invention is to provide a vehicle brake fluid pressure control device including a pump using an eccentric cam, in which brake fluid in a reservoir is sufficiently returned to a fluid pressure source side.

In order to solve the above problems, a vehicle brake hydraulic pressure control device according to the present invention includes an inlet valve interposed in a hydraulic pressure path from a hydraulic pressure source to a wheel brake, and a hydraulic pressure path from the wheel brake to a reservoir. An outlet valve, a pump interposed in a hydraulic path from the reservoir to the hydraulic pressure source and driven by a motor having an eccentric cam, anti-lock brake control, and pressure reduction of the anti-lock brake control. A control unit for performing control of returning brake fluid stored in the reservoir to the hydraulic pressure source side by driving the motor.
The control unit estimates a reservoir usage amount corresponding to an increase amount of the brake fluid in the reservoir from an initial state, drives the motor until the reservoir usage amount becomes 0, and then further rotates by one rotation After the motor is rotated excessively, the motor is stopped.

  According to this configuration, the brake fluid in the reservoir can be sufficiently returned to the hydraulic pressure source side without being affected by the variation in the discharge amount due to the rotational position of the eccentric cam.

  Further, the control unit may be configured to determine that the reservoir usage amount has become 0 when a predetermined time has elapsed from the end of the pressure reduction control.

  According to this, it is possible to determine that the reservoir usage amount has become 0 by a simple control that only looks at the driving time of the motor.

  The control unit may further include, in the pressure reduction control, an amount of brake fluid flowing into the reservoir from the wheel brakes based on a hydraulic pressure at the start of the pressure reduction control and a hydraulic pressure at the end of the pressure reduction control. Is estimated from the number of revolutions of the motor, and the discharge amount corresponding to the amount of brake fluid discharged from the reservoir is estimated from the rotation speed of the motor. It may be configured to determine the reservoir usage based on the value.

  According to this, an accurate reservoir usage amount can be obtained by performing a calculation using both the consumed liquid amount and the discharge amount.

  ADVANTAGE OF THE INVENTION According to this invention, in the vehicle brake fluid pressure control apparatus provided with the pump using an eccentric cam, the brake fluid in a reservoir can be fully returned to the fluid pressure source side.

1 is a configuration diagram of a vehicle including a vehicle brake hydraulic pressure control device according to an embodiment. It is a block diagram which shows the structure of a hydraulic unit. It is a figure which shows the relationship between a pump and an eccentric cam, and the figure which shows the state which pressed the plunger of the illustration left side by the eccentric cam, and the figure which shows the state which pressed the plunger of the illustration right side by the eccentric cam. is there. FIG. 3 is a block diagram illustrating a configuration of a control unit. It is a figure which shows a hydraulic-pressure estimation map (a) and a consumption liquid estimation map (b). It is a figure showing an ejection amount estimation map. It is a figure showing a target discharge time setting map. 5 is a flowchart illustrating a process performed by a control unit. 5 is a time chart illustrating control by a control unit. 5 is a time chart illustrating control by a control unit.

Next, embodiments of the present invention will be described in detail with reference to the drawings as appropriate.
As shown in FIG. 1, a vehicle brake fluid pressure control device 1 is a device that appropriately controls a braking force applied to each wheel 3 of a vehicle 2 that is a four-wheeled vehicle. The vehicle brake fluid pressure control device 1 mainly includes a fluid pressure unit 10 in which a fluid pressure path and various components are provided, and a control unit 100 for appropriately controlling various components in the fluid pressure unit 10.

  Each wheel 3 is provided with a wheel brake FL, RR, RL, FR, respectively. Each wheel brake FL, RR, RL, FR has a braking force by a hydraulic pressure supplied from a master cylinder 5 which is a hydraulic pressure source. Is provided. The master cylinder 5 and the wheel cylinder 4 are connected to the hydraulic unit 10, respectively. The brake fluid pressure generated in the master cylinder 5 according to the depression force of the brake pedal 6 is supplied to the wheel cylinder 4 after being controlled by the control unit 100 and the fluid pressure unit 10.

  The control unit 100 is connected with a pressure sensor 91 that detects the hydraulic pressure of the master cylinder 5 (master cylinder pressure Pm) and a wheel speed sensor 92 that detects the wheel speed Vw of each wheel 3. The control unit 100 includes, for example, a CPU (Central Processing Unit), a RAM (Random Access Memory), a ROM (Read Only Memory), and an input / output circuit, and receives inputs from the pressure sensor 91 and the wheel speed sensor 92 and the ROM. The control for increasing or decreasing the hydraulic pressure of the wheel brakes FL, RR, RL, FR is performed by performing various types of arithmetic processing based on programs and data stored in the CPU.

  As shown in FIG. 2, the hydraulic unit 10 is disposed between the master cylinder 5 and the wheel brakes FL, RR, RL, FR. The two output ports 5a, 5b of the master cylinder 5 are connected to the inlet port 11a of the hydraulic unit 10, and the outlet port 11b is connected to each wheel brake FL, RR, RL, FR. In a normal state, the hydraulic pressure path communicates from the inlet port 11a to the outlet port 11b in the hydraulic unit 10, so that the pedaling force of the brake pedal 6 is transmitted to the wheel brakes FL, RR, RL, FR. It is supposed to be.

  The hydraulic unit 10 is provided with a base 11 and four inlet valves 13, four outlet valves 14, and four check valves 13a corresponding to the wheel brakes FL, RR, RL, FR. The hydraulic unit 10 has two reservoirs 16, two pumps 17, two orifices 17a, and motors for driving the two pumps 17 corresponding to the respective output hydraulic paths 19A corresponding to the output ports 5a and 5b. An electric motor 21 is provided as an example.

The inlet valve 13 is a normally-open proportional solenoid valve disposed on a hydraulic path from the master cylinder 5 to each wheel brake FL, RR, RL, FR (upstream of each wheel brake FL, RR, RL, FR). is there. Since the inlet valve 13 is normally open, the brake fluid pressure is allowed to be transmitted from the master cylinder 5 to each wheel brake FL, RR, RL, FR. Further, the inlet valve 13 is closed by the control unit 100 when the wheel 3 is about to be locked, thereby shutting off the hydraulic pressure transmitted from the brake pedal 6 to each wheel brake FL, RR, RL, FR.
Although not shown in detail, the valve body of the inlet valve 13 is urged toward the master cylinder 5 by an electromagnetic force corresponding to the applied current, and the urging force causes the fluid of the wheel brakes FL, RR, RL, and FR to be urged. The pressure can be adjusted.

  The outlet valve 14 is disposed on a hydraulic path from each of the wheel brakes FL, RR, RL, FR to the master cylinder 5 (a hydraulic path from the hydraulic path on the wheel cylinder 4 side of the inlet valve 13 to the reservoir 16, the pump 17, and the master cylinder 5). A normally closed solenoid valve arranged on the pressure path). Specifically, the outlet valve 14 is interposed in a hydraulic path from each of the wheel brakes FL, RR, RL, FR to the reservoir 16. The outlet valve 14 is normally closed, but is opened by the control unit 100 when the wheel 3 is about to be locked, so that the hydraulic pressure applied to each of the wheel brakes FL, RR, RL, and FR is reduced by each of the reservoirs. Release to 16.

  The check valve 13a is connected in parallel to each inlet valve 13. The check valve 13a is a valve that permits only the flow of the brake fluid from each of the wheel brakes FL, RR, RL, and FR to the master cylinder 5, and the input valve 13a when the input from the brake pedal 6 is released. Is closed, the flow of brake fluid from each of the wheel brakes FL, RR, RL, FR to the master cylinder 5 is permitted.

The reservoir 16 has a function of absorbing the brake fluid that is released when each of the outlet valves 14 is opened.
The pump 17 is disposed on a hydraulic path from the reservoir 16 to the master cylinder 5. The pump 17 has a function of sucking the brake fluid absorbed by the reservoir 16 and returning the brake fluid to the master cylinder 5 via the orifice 17a.

  The opening and closing states of the inlet valve 13 and the outlet valve 14 are controlled by the control unit 100, so that the hydraulic pressures of the wheel brakes FL, RR, RL, and FR in the wheel cylinders 4 (hereinafter, referred to as “wheel cylinder pressures Pw”). ) Control. For example, in a normal state in which the inlet valve 13 is opened and the outlet valve 14 is closed, if the brake pedal 6 is depressed, the hydraulic pressure from the master cylinder 5 is transmitted to the wheel cylinder 4 as it is, and the pressure is increased. When the valve 13 is closed and the outlet valve 14 is opened, the brake fluid flows out of the wheel cylinder 4 to the reservoir 16 side to reduce the pressure, and when both the inlet valve 13 and the outlet valve 14 are closed, the wheel cylinder pressure Pw Is held. If an appropriate current that does not lead to the fully closed state is supplied to the inlet valve 13 while the outlet valve 14 is closed while the master cylinder pressure Pm is increasing, the wheel from the master cylinder 5 is moved in accordance with the current. The flow of the brake fluid into the cylinder 4 is restricted, and the wheel cylinder pressure Pw can be gradually increased.

  As shown in FIG. 3, the electric motor 21 has an eccentric cam 21a for driving the two pumps 17. The eccentric cam 21a is a disc-shaped cam, and is fixed to the output shaft with its center eccentric from the center of the output shaft of the electric motor 21. One pump 17 is provided on each side of the eccentric cam 21a. Since the two pumps 17 have the same structure, only one is illustrated in FIG. 3 as a representative.

  The pump 17 includes a bottomed cylindrical cylinder 171, a piston 172 movably provided in the cylinder 171, a return spring 173 for urging the piston 172 toward the eccentric cam 21 a, a discharge valve 174, and a suction valve. 175 and a cap 176.

  The cylinder 171 is fitted and fixed in a pump hole 11H formed in the base body 11 with the opening facing the eccentric cam 21a. A through-hole-shaped discharge passage 171A is formed at the bottom of the cylinder 171. The periphery of the opening on the outlet side (cap 176 side) of the discharge passage 171A is a tapered valve seat 171B.

  The cap 176 is fitted and fixed in the pump hole 11H so as to cover the bottom of the cylinder 171. Between the cap 176 and the cylinder 171, a flow path 176A for connecting the discharge path 171A and the discharge flow path 11A formed in the base 11 is formed. Note that the discharge passage 11A is connected to the master cylinder 5 and the like (see FIG. 2).

  The discharge valve 174 is provided between the cap 176 and the bottom of the cylinder 171 together with the spring SP1, and is urged to the valve seat 171B by the spring SP1.

  The piston 172 includes a cylindrical piston portion 172A and a large-diameter piston portion 172B, and is biased by the return spring 173 toward the eccentric cam 21a. One end of the cylindrical piston portion 172A is arranged at a position where it can contact the eccentric cam 21a, and the other end is press-fitted into the large-diameter piston portion 172B and fixed.

  The large-diameter piston portion 172B is slidably engaged with the inner peripheral surface of the cylinder 171. The large-diameter piston portion 172B is formed in a bottomed cylindrical shape that opens toward the cylindrical piston portion 172A. A suction hole B1 having a through-hole shape is formed at the bottom of the large-diameter piston portion 172B. The periphery of the opening on the outlet side (cap 176 side) of the suction passage B1 is a valve seat portion B3 formed in a tapered shape.

  A bottomed cylindrical retainer 177 is provided outside the bottom of the large-diameter piston portion 172B. The retainer 177 is arranged so that the opening faces the large-diameter piston portion 172B, and a through hole 177A is formed at the bottom thereof. In the retainer 177, a suction valve 175 and a spring SP2 are provided. The suction valve 175 is urged toward the valve seat B3 by a spring SP2.

  A plurality of grooves B2 along the axial direction are formed on the inner peripheral surface of the large-diameter piston portion 172 into which the cylindrical piston portion 172A is press-fitted. One end of the groove B2 is open to the annular space 11C around the cylindrical piston portion 172A, and the other end is connected to the suction passage B1. The annular space 11C is connected to a reservoir 16 (see FIG. 2) via a suction passage 11B formed in the base 11.

Next, the operation of the pump 17 will be described.
When the eccentric cam 21a presses the piston 172, the piston 172 moves against the urging force of the return spring 173, and the pressure in the cylinder 171 increases. As a result, the suction valve 175 closes and the discharge valve 174 opens, so that the brake fluid in the cylinder 171 is pumped to the master cylinder 5 side.

  When the eccentric cam 21a rotates away from the piston 172, the piston 172 moves by the urging force of the return spring 173, and the pressure in the cylinder 171 decreases. As a result, the discharge valve 174 closes and the suction valve 175 opens, so that the brake fluid in the reservoir 16 is sucked into the cylinder 171.

Next, details of the control unit 100 will be described.
As shown in FIG. 4, the control unit 100 includes a wheel deceleration calculation unit 111, a vehicle deceleration calculation unit 112, a fluid pressure estimation unit 113, a rotation speed acquisition unit 114, and an antilock brake (hereinafter, referred to as “ABS”). Control means 120, road surface friction coefficient (hereinafter referred to as “road surface μ”) estimating means 131, liquid consumption estimating means 132, discharge amount estimating means 133, target discharge time setting means 141, reservoir usage estimating means 142, target rotation It comprises a number setting means 150, a valve drive section 160, a motor drive section 170 and a storage device 190.

  The wheel deceleration calculating means 111 has a function of calculating the wheel deceleration Aw of each wheel 3 based on the wheel speed Vw of each wheel 3 acquired from the wheel speed sensor 92. Here, the deceleration has the same meaning as the acceleration. A negative value indicates that the vehicle is decelerating, and a positive value indicates that the vehicle is accelerating. The wheel deceleration Aw can be calculated, for example, by subtracting the previous value from the current value of the wheel speed Vw. The wheel deceleration calculation unit 111 outputs the calculated wheel deceleration Aw of each wheel 3 to the ABS control unit 120 and the road surface μ estimation unit 131.

  The vehicle body deceleration calculating means 112 has a function of calculating the vehicle body deceleration Ac based on the wheel speed Vw of each wheel 3 acquired from the wheel speed sensor 92. The vehicle body deceleration Ac can be calculated, for example, by subtracting the previous value from the current value of the vehicle speed Vc calculated from the wheel speed Vw. At the time of the ABS control, the vehicle body deceleration Ac is calculated from the wheel speed Vw at the start of the previous pressure increase and the wheel speed Vw at the start of the current pressure increase. The vehicle body deceleration calculating means 112 outputs the calculated vehicle body deceleration Ac to the road surface μ estimating means 131.

  The hydraulic pressure estimating means 113 calculates the wheel cylinder pressure of each wheel 3 based on the master cylinder pressure Pm obtained from the pressure sensor 91 and the control history of the inlet valve 13 and the outlet valve 14 output from the ABS control means 120. It has a function of estimating Pw. The hydraulic pressure estimating means 113 outputs the estimated wheel cylinder pressures Pw to the consumed liquid amount estimating means 132 and the road surface μ estimating means 131.

  The rotation speed obtaining means 114 has a function of obtaining information on the rotation speed of the electric motor 21. Specifically, the rotation speed acquisition unit 114 obtains the back electromotive voltage of the electric motor 21 as information on the rotation speed of the electric motor 21. The number-of-rotations acquisition unit 114 outputs the acquired information on the number of rotations of the electric motor 21 to the discharge amount estimation unit 133.

  The ABS control unit 120 determines whether or not to execute the ABS control based on the wheel speed Vw of each wheel 3 obtained from the wheel speed sensor 92 and each wheel deceleration Aw calculated by the wheel deceleration calculation unit 111. The function to determine for each wheel 3 and, when it is determined to be executed, to determine for each wheel 3 the instruction of the hydraulic pressure control during ABS control (instruction of any one of pressure reduction control, holding control and pressure increase control). Have.

  Specifically, the ABS control means 120 calculates the slip amount SL of each wheel 3 based on the wheel speed Vw of each wheel 3 and the vehicle speed Vc estimated from each wheel speed Vw. As the slip amount SL, for example, a value obtained by subtracting the wheel speed Vw from the vehicle speed Vc, a slip ratio represented by (Vc−Vw) / Vc, or the like can be used.

  Then, the ABS control means 120 determines that the wheel 3 is about to be locked when the slip amount SL is equal to or more than the predetermined pressure reduction threshold SLth and the wheel deceleration Aw is equal to or less than 0, and issues an instruction for the hydraulic pressure control. Is determined to be pressure reduction control. When the wheel deceleration Aw is greater than 0, the ABS control means 120 determines the instruction of the hydraulic control to be the holding control. Further, when the slip amount SL is less than the pressure reduction threshold value SLth and the wheel deceleration Aw is equal to or less than 0, the ABS control means 120 determines the pressure control instruction to be the pressure increase control. The ABS control unit 120 outputs information on the determined hydraulic pressure control instruction (instruction of pressure reduction, holding or pressure increase) to the valve driving unit 160.

  The road surface μ estimating means 131 has a function of estimating the road surface μ. Specifically, when the ABS control is started, the road surface μ estimating means 131 calculates the wheel deceleration Aw of each wheel 3 calculated by the wheel deceleration calculating means 111 and the wheel cylinder pressure Pw estimated by the hydraulic pressure estimating means 113. Based on the above, the road surface μ corresponding to each wheel 3 is estimated. Specifically, the road surface μ estimating means 131 estimates the road surface μ corresponding to each wheel 3 based on the wheel deceleration Aw of each wheel 3, each wheel cylinder pressure Pw, and a road surface friction coefficient estimation map.

  Here, the road surface friction coefficient estimation map is a map for associating the magnitude (absolute value) of the wheel deceleration Aw, the wheel cylinder pressure Pw, and the road surface μ, and is set in advance by experiments, simulations, and the like. . The road surface friction coefficient estimation map is set such that as the magnitude of the wheel deceleration Aw increases, the road surface μ decreases, and as the wheel cylinder pressure Pw decreases, the road surface μ decreases. If the magnitude of the wheel cylinder pressure Pw or the wheel deceleration Aw is a value other than the value shown in the road surface friction coefficient estimation map, the road surface μ estimating means 131 estimates the road surface μ by linear interpolation.

When the pressure increase control is executed twice during the ABS control, the road surface μ estimating means 131 estimates the road surface μ based on the vehicle body deceleration Ac calculated by the vehicle body deceleration calculating means 112 thereafter. I do. More specifically, the road surface μ estimating means 131 sets the road surface μ to a lower value as the magnitude of the vehicle body deceleration Ac is smaller.
The road surface μ estimating means 131 outputs the estimated road surface μ to the target discharge time setting means 141.

  In the pressure reduction control of the ABS control, the consumed liquid amount estimating means 132 uses the wheel brake pressures FL, RR, RL, and FR based on the wheel cylinder pressure Pw at the start of the pressure reduction control and the wheel cylinder pressure Pw at the end of the pressure reduction control. Has a function of estimating the amount of consumed fluid corresponding to the amount of brake fluid that has flowed into the reservoir 16 for each wheel 3. Specifically, the consumed liquid amount estimating unit 132 estimates the current value of the wheel cylinder pressure Pw for each unit time ΔT based on the previous value of the wheel cylinder pressure Pw, the unit time ΔT, and the hydraulic pressure estimation map. I do.

  Here, as shown in FIG. 5A, the hydraulic pressure estimation map is a map showing a temporal change of the wheel cylinder pressure Pw during the pressure reduction control of the ABS control, and is set in advance for each wheel 3 by an experiment, a simulation, or the like. Have been. For example, when the previous value of the wheel cylinder pressure Pw is Pw3, the consumed liquid amount estimating unit 132 estimates the current value of the wheel cylinder pressure Pw as Pw2 based on the unit time ΔT and the hydraulic pressure estimation map. .

  Then, the consumed liquid amount estimation means 132 estimates the consumed liquid amount Vs based on the current value of the estimated wheel cylinder pressure Pw, the previous value of the wheel cylinder pressure Pw, and the consumed liquid amount estimation map.

  Here, the consumption liquid amount estimation map is a map for associating the wheel cylinder pressure Pw with the hydraulic pressure loss, as shown in FIG. 5B, and is set in advance by an experiment, a simulation, or the like. The liquid consumption estimation map is set such that the smaller the wheel cylinder pressure Pw, the smaller the hydraulic pressure loss. For example, if the previous value of the wheel cylinder pressure Pw is Pw3 and the current value is Pw2, the consumed liquid amount estimating means 132 determines the hydraulic pressure loss at the wheel cylinder pressure Pw3 based on the consumed liquid amount estimation map. D3 and the hydraulic pressure loss D2 at the wheel cylinder pressure Pw2 are estimated. Then, the fluid consumption Vs is estimated by subtracting the fluid pressure loss D2 from the fluid pressure loss D3.

  The consumed liquid amount estimating means 132 calculates the consumed liquid amount Vs for each unit time ΔT during the pressure reduction control. As a result, the wheel cylinder pressure Pw (for example, Pw3) at the start of the pressure reduction control and the pressure reduction control Based on the wheel cylinder pressure Pw at the end (for example, Pw1), the total liquid consumption during the pressure reduction control is estimated. The consumed liquid amount estimating means 132 outputs the estimated consumed liquid amount Vs to the reservoir used amount estimating means 142.

  The discharge amount estimating means 133 has a function of estimating the discharge amount corresponding to the amount of brake fluid discharged from the reservoir 16 by driving the pump 17 from the rotation speed of the electric motor 21 in the pressure reduction control of the ABS control. . Specifically, the discharge amount estimating unit 133 determines the discharge amount Vd based on the rotation speed (back electromotive voltage) of the electric motor 21 acquired by the rotation speed acquisition unit 114 and the discharge amount estimation map for each unit time ΔT. Is estimated.

  Here, as shown in FIG. 6, the discharge amount estimation map is a map for associating the back electromotive voltage of the electric motor 21 with the discharge amount Vd, and is set in advance by an experiment, a simulation, or the like. The discharge amount estimation map is set so that the discharge amount Vd increases as the magnitude of the back electromotive voltage of the electric motor 21 increases. The discharge amount estimation means 133 outputs the estimated discharge amount Vd to the reservoir use amount estimation means 142.

  The target discharge time setting means 141 has a function of setting a target discharge time Td as an example of a predetermined time based on the road surface μ estimated by the road surface μ estimating means 131. Specifically, the target discharge time setting means 141 sets the target discharge time Td based on the road surface μ and the target discharge time setting map. Here, as shown in FIG. 7, the target discharge time setting map is a map for associating the road surface μ with the target discharge time Td, and is set in advance by experiments, simulations, or the like. The target discharge time setting map is set such that the higher the road surface μ, the shorter the target discharge time Td. Thereby, the target discharge time setting means 141 sets the target discharge time Td to a longer time as the road surface μ is lower, and sets the target discharge time Td to a shorter time as the road surface μ is higher.

In addition, during the ABS control, when the next pressure reduction control is started before the target discharge time Td has elapsed from the end of the pressure reduction control, the target discharge time setting means 141 outputs the road surface μ and the target discharge time setting map. , The target ejection time Td is reset.
The target discharge time setting unit 141 outputs the set target discharge time Td to the target rotation speed setting unit 150 and the motor drive unit 170.

The reservoir use amount estimating means 142 has a function of estimating the reservoir use amount corresponding to the increase amount of the brake fluid in the reservoir 16 from the initial state (empty state) in the pressure reduction control of the ABS control. More specifically, the reservoir use amount estimating unit 142 calculates, for each unit time ΔT, the discharge amount Vd estimated by the discharge amount estimating unit 133, the consumed liquid amount Vs estimated by the consumed liquid amount estimating unit 132, and the last time of the reservoir used amount. based on the value _{Vr n-1,} we obtain the reservoir usage Vr _n. Specifically, reservoir amount estimating means 142, the previous value Vr _n-1 reservoir usage, by adding a value obtained by subtracting the discharge amount Vd from fluid consumption Vs, the reservoir amount Vr n _(current value) calculating the _{(Vr n = Vr n-1} + (Vs-Vd)). Reservoir amount estimating means 142 outputs the reservoir usage Vr _n estimated the target rotational speed setting means 150.

Target rotational speed setting means 150, a target discharge time Td target discharge time setting unit 141 has set, on the basis of the reservoir the amount Vr _n the reservoir amount estimating means 142 estimates, the target rotational speed of the electric motor 21 It has a function to set. Specifically, the target rotation speed setting means 150 sets a discharge time counter value TdC from the target discharge time Td. Specifically, the target rotation speed setting means 150 sets the target discharge time Td to the discharge time counter value TdC during the pressure reduction control of the ABS control, and after the pressure reduction control (during the holding control and the pressure increase control), For each unit time ΔT, a value obtained by subtracting the unit time ΔT from the previous value of the discharge time counter value TdC is set as the discharge time counter value TdC.

Then, the target rotational speed setting means 150 calculates a target discharge amount Vt by dividing the reservoir usage Vr _n in the discharge time counter value TDC, and the target discharge quantity Vt calculated on the basis of the target rotation speed setting map , The target rotation speed Rt is set. Here, the target rotation speed setting map is a map for associating the target discharge amount Vt with the target rotation speed Rt, and is set in advance by experiments, simulations, and the like. The target rotation speed setting map is set such that the target rotation speed Rt increases as the target discharge amount Vt increases. The target rotation speed setting unit 150 outputs information on the set target rotation speed Rt to the motor drive unit 170.

  The valve drive unit 160 has a function of controlling the wheel cylinder pressure Pw by controlling the inlet valve 13 and the outlet valve 14 based on the information of the fluid pressure control instruction output from the ABS control unit 120. ing.

  Specifically, when the instruction of the hydraulic pressure control is pressure reduction control, the valve driving unit 160 closes the inlet valve 13 and opens the outlet valve 14 by flowing current through the inlet valve 13 and the outlet valve 14, Control is performed to reduce the wheel cylinder pressure Pw. In addition, when the instruction of the hydraulic pressure control is the holding control, the valve driving unit 160 allows both the inlet valve 13 and the outlet valve 14 to flow by supplying a current to the inlet valve 13 and not supplying a current to the outlet valve 14. Both are closed to control to maintain the wheel cylinder pressure Pw.

  Furthermore, when the instruction of the fluid pressure control is the pressure increase control, the valve driving unit 160 closes the outlet valve 14 by not flowing the current to the outlet valve 14, and does not flow the current to the inlet valve 13, or By flowing a drive current corresponding to the indicated hydraulic pressure, the differential pressure between the upstream and downstream of the inlet valve 13 is controlled so that the wheel cylinder pressure Pw is increased at an intended pressure increasing rate.

  The motor drive unit 170 controls the driving of the electric motor 21 that drives the pump 17 based on information output from the target discharge time setting unit 141, the target rotation speed setting unit 150, and the like, thereby reducing the pressure in ABS control. It has a function of executing control to return the brake fluid stored in the reservoir 16 by the control from the reservoir 16 side to the master cylinder 5 side.

  Specifically, the motor drive unit 170 starts driving the electric motor 21 when starting pressure reduction control of the ABS control. More specifically, the motor drive unit 170 allows the electric motor 21 to pass the electric motor 21 at the target rotation speed Rt by flowing a current corresponding to the target rotation speed Rt set by the target rotation speed setting means 150 to the electric motor 21 during the ABS control. Drive.

  Then, when the target discharge time Td has elapsed since the end of the pressure reduction control, the motor drive unit 170 determines that the reservoir usage amount has become 0, and then rotates the electric motor 21 by one additional rotation. Then, the electric motor 21 is stopped.

  Specifically, the motor driving unit 170 sets an extra time Te required for the electric motor 21 rotating at the target rotation speed Rt to make one rotation based on the target rotation speed Rt. More specifically, for example, when the unit of the target rotation speed Rt is rps (rotation / second), the motor driving unit 170 sets the extra time Te to 1 / Rt (second).

  Note that the setting of the extra time Te may be performed at any timing during the pressure reduction control, after the target rotation speed Rt is set. The setting of the extra time Te may be performed after the pressure reduction control. In this case, the setting may be performed between the end of the pressure reduction control and the elapse of the target discharge time Td.

  Then, after the target discharge time Td elapses from the end of the pressure reduction control, the motor drive unit 170 continues to rotate the electric motor 21 at the target rotation speed Rt for the extra time Te, and then passes the current to the electric motor 21. Is stopped, the driving of the electric motor 21 is stopped.

  The storage device 190 is a device that stores a threshold value, a map, an estimated value, a calculated value, and the like for processing in each unit described above.

Next, a process performed by the control unit 100 configured as described above will be described. Note that the process of FIG. 8 is repeatedly performed for each predetermined control cycle (unit time ΔT).
As shown in FIG. 8, the control unit 100 first determines whether or not the ABS control is being performed (S11). If the ABS control is not being performed (S11, No), the control unit 100 ends the current process.

On the other hand, when the ABS control is being performed (S11, Yes), the control unit 100 estimates the road surface μ (S23). Further, the control unit 100 estimates the consumed liquid amount Vs (S24) and estimates the discharge amount Vd (S25). Then, the control unit 100, the discharge amount Vd, fluid consumption Vs and on the basis of the previous value _{Vr n-1} reservoir usage with estimating the reservoir amount Vr _n (S26), the target discharge time based on road surface μ Td is set (S27). Further, the control unit 100, (S28) sets the target speed Rt of the electric motor 21 on the basis of the reservoir the amount Vr _n and the target discharge time Td, extra time to set the Te based on the target speed Rt ( S29).

  After step S29, the control unit 100 drives the electric motor 21 at the set target rotation speed Rt (S32), and returns the brake fluid accumulated in the reservoir 16 from the reservoir 16 to the master cylinder 5 side.

  Then, the control unit 100 determines whether or not the target discharge time Td has elapsed since the end of the pressure reduction control (S33). If the target ejection time Td has not elapsed (S33, No), the control unit 100 ends the current process. On the other hand, when the target discharge time Td has elapsed (S33, Yes), the control unit 100 determines that the reservoir usage has become 0, and the electric motor 21 for another rotation (extra time Te) from the determination. Is rotated (S34). After step S34, almost all of the brake fluid in the reservoir 16 returns to the master cylinder 5 side and the reservoir 16 is almost empty, so the control unit 100 stops driving the electric motor 21 (S35). Then, the current process ends.

Note that if the holding control or the pressure increasing control of the ABS control is continuously performed after step S35, the control unit 100 performs step S26 because the amount of the brake fluid in the reservoir 16 does not increase from the empty state. in estimates that reservoir usage Vr _n is 0. Thereby, the control unit 100 sets the target rotation speed Rt of the electric motor 21 to 0 in step S28. As a result, the control unit 100 ends the current process without driving the electric motor 21 even during the ABS control.

Next, an example of control by the control unit 100 will be described.
As shown in FIG. 9, when the ABS control is started (ON) at time t1 and the pressure reduction control is started, the inlet valve 13 is closed and the outlet valve 14 is opened, so that the brake fluid flows from the wheel cylinder 4. flows into the reservoir 16, the reservoir amount Vr n _(the amount of brake fluid in the reservoir 16) increases. Here, the reservoir amount Vr _n indicated by a solid line, shows a reservoir used amount obtained by calculation, reservoir usage indicated by a broken line shows the actual reservoir usage.

Further, when starting the ABS control for each control cycle (unit time [Delta] T), the reservoir amount Vr _n and the target discharge time Td, the discharge time counter value TDC, the target speed Rt is set, the set target speed Rt Drives the electric motor 21. During the pressure reduction control (time t1 to t2), the pump 17 is driven by the drive of the electric motor 21 and a part of the brake fluid is discharged from the reservoir 16 to the master cylinder 5 side. If towards the amount of brake fluid flowing into the reservoir 16 is large, the reservoir amount Vr _n gradually increases.

At time t2, the pressure-reducing control is completed and starts the holding control, that the outlet valve 14 is closed, since the flow of brake fluid from the wheel cylinder 4 into the reservoir 16 is stopped, an increase in reservoir amount Vr _n Stops. Then, since the brake fluid by the drive of the pump 17 based on the target speed Rt it is discharged from the reservoir 16 to the master cylinder 5 side, the reservoir amount Vr _n decreases.

At time t3, when starting the next pressure reduction control before (before discharge time counter value TdC is 0) the target discharge time Td from the end (time t2) of the pressure reduction control has elapsed, again reservoir amount Vr _n increases I will do it.

Then, at time t4, the pressure reduction control is ended again to start holding control, the increase in reservoir amount Vr _n stops, master from the brake fluid within the reservoir 16 by the drive of the pump 17 based on the target speed Rt discharged into the cylinder 5 side, decreases again reservoir usage Vr _n.

Then, at time t5, the target discharge time Td from the end (time t4) of the pressure reduction control has elapsed (when the discharge time counter value TdC becomes 0), the control unit 100 determines that the reservoir amount Vr _n is 0 I do. Thereafter, the control unit 100 continues the rotation of the electric motor 21 until the extra time Te elapses from the time t5, and stops the drive of the electric motor 21 after the extra time Te elapses (t6). Thereafter, as shown at time t6 to t7, since the reservoir amount Vr _n is 0, even during the ABS control, unless again the pressure reduction control is started, will not be electric motor 21 is driven.

By the way, in the present embodiment, the target discharge time Td is set based on the road surface μ and the target discharge time setting map in FIG. 7, and therefore, as shown in FIG. When Td is set to a long time Td _Low (large value), the discharge time counter value TdC becomes a large value TdC _Low , and when the road surface μ is high, the target discharge time Td is set to a short time Td _High (small value). As a result, the discharge time counter value TdC becomes a small value TdC _High . The target speed Rt is to be set based on the target discharge amount Vt calculated by dividing the reservoir usage Vr _n in the discharge time counter value TDC, when the road surface μ is low, a large discharge time counter value TDC The target rotation speed Rt is set to a small rotation speed Rt _Low by the value TdC _Low , and when the road surface μ is high, the target rotation speed Rt is set to the large rotation speed Rt by the discharge time counter value TdC being a small value TdC _High. Set to _High .

Therefore, on the low μ road where the road noise is small, as shown by the solid line in FIG. 10, the electric motor 21 is driven at a small target rotation speed Rt _Low for a long time (Td _Low + Te) from time t12 to t14. By doing so, the operating noise of the electric motor 21 can be made inconspicuous. On the other hand, on the high μ road where the road noise increases, the electric motor 21 is driven at a large target rotation speed Rt _High and for a short time (Td _High + Te) between times t12 and t13 as shown by a two-dot chain line in FIG. Even so, the operating noise of the electric motor 21 can be made inconspicuous.

According to the above, the following effects can be obtained in the present embodiment.
After estimated reservoir usage Vr _n has to drive the electric motor 21 until 0, since the electric motor 21 is stopped from further cause extra rotate one revolution by the electric motor 21, the rotational position of the eccentric cam 21a The brake fluid in the reservoir 16 can be sufficiently returned to the master cylinder 5 side without being affected by the variation in the discharge amount due to the above.

When the target discharge time Td from the end of the pressure reduction control has elapsed, the control unit 100 determines that the reservoir amount Vr _n is 0, the driving of the electric motor 21 that reservoir usage Vr _n is 0 The determination can be made by simple control just by looking at the time.

  If the time (Td + Te) has elapsed since the end of the pressure reduction control, the electric motor 21 is stopped even during the ABS control, so that the drive time of the electric motor 21 during the ABS control is not unnecessarily long. Also, it is possible to suppress the occupant from feeling uncomfortable due to the operation noise of the electric motor 21.

  If the next pressure reduction control is started before the target discharge time Td has elapsed from the end of the pressure reduction control, the target discharge time Td is reset based on the road surface μ. Is reset. Thus, the electric motor 21 can be driven in an appropriate time after the end of each pressure reduction control.

Further, the amount of brake fluid in the reservoir 16 (reservoir amount Vr _n), so to set a target speed Rt of the electric motor 21 based on the target discharge time Td which is set based on the road surface mu, the vehicle 2 The operating speed of the electric motor 21 can be made inconspicuous according to the road surface μ of the road surface on which the vehicle is traveling.

Further, fluid consumption Vs, so obtaining a reservoir amount Vr _n by using the previous value Vr _n-1 of the discharge amount Vd and the reservoir usage, for example, than only fluid consumption Vs when obtaining a reservoir usage, a reservoir amount Vr _n can be accurately determined.

  In addition, since the target discharge time Td is set to a shorter time as the road surface μ is higher, the operation noise is less noticeable even when the electric motor 21 is driven at a high rotation speed for a short time on a high μ road where road noise increases. be able to. In addition, since the target discharge time Td is set to a longer time as the road surface μ is lower, the operation noise is reduced by driving the electric motor 21 at a low rotation speed over a long time on a low μ road where the road noise is small. It can be less noticeable.

  In addition, when the ABS control is started, the road surface μ is estimated based on each wheel cylinder pressure Pw and the wheel deceleration Aw of each wheel 3, so that the road surface μ can be estimated at an initial stage when the ABS control is started. . Thus, for example, when the ABS control is performed on a low μ road, the electric motor 21 is controlled in accordance with the low μ road, as compared with a method of setting the road surface μ to a high μ at an initial stage of starting the ABS control. Since the number of rotations can be reduced, the operating noise of the electric motor 21 can be made inconspicuous.

  Further, when the pressure increase control is executed twice during the ABS control, the road surface μ is estimated thereafter based on the vehicle body deceleration Ac, so that the road surface μ can be accurately estimated.

The present invention is not limited to the above-described embodiment, and can be used in various forms as exemplified below.
For example, the present invention may be applied to a vehicle brake hydraulic pressure control device that performs a vehicle attitude control other than the ABS control together with the ABS control.

  Further, in the above-described embodiment, when the control unit 100 executes the pressure increase control twice during the ABS control, the control unit 100 estimates the road surface μ based on the vehicle body deceleration Ac thereafter. However, the present invention is not limited to this. For example, the control unit may be configured to estimate the road surface μ based on the vehicle body deceleration after executing the pressure increase control three or more times during the ABS control. Further, the control unit may be configured to estimate the road surface μ based on each wheel cylinder pressure and the wheel deceleration of each wheel regardless of the number of executions of the pressure increase control.

  In the above-described embodiment, the control unit 100 uses the estimated wheel cylinder pressure Pw for control. However, the present invention is not limited to this. For example, the control unit may use a wheel cylinder pressure acquired from a sensor that detects a wheel cylinder pressure of each wheel for control.

In the above embodiment, the control unit 100, the control for each cycle, but there was a configuration for calculating the reservoir amount Vr _n and the target rotational speed Rt, but is not limited thereto. For example, the control unit may be configured to calculate the reservoir usage amount and the target rotation speed at the end of one pressure reduction control.

  Here, to explain an example, when the pressure reduction control is finished, the wheel cylinder pressure Pw3 at the start of the pressure reduction control, the control time Tc of the pressure reduction control, Based on the pressure estimation map, the wheel cylinder pressure Pw1 at the end of the pressure reduction control is estimated. Then, as shown in FIG. 5B, based on the wheel cylinder pressures Pw1 and Pw3 and the consumed liquid amount estimation map, a hydraulic pressure loss D1 at the wheel cylinder pressure Pw1 and a hydraulic pressure loss D1 at the wheel cylinder pressure Pw3 are obtained. The hydraulic pressure loss D3 is estimated. Then, by subtracting the hydraulic pressure loss D1 from the hydraulic pressure loss D3, the consumed liquid amount during the pressure reduction control is estimated. Further, for each unit time during the pressure reduction control, the discharge amount is estimated based on the rotation speed of the motor (back electromotive force) and the discharge amount estimation map shown in FIG. 6, and the respective discharge amounts for each unit time are integrated. To estimate the total discharge amount. Then, the reservoir use amount can be calculated by adding a value obtained by subtracting the total discharge amount from the consumed liquid amount during the pressure decrease control to the reservoir use amount at the end of the previous pressure reduction control. Further, regarding the target rotation speed, at the end of the pressure reduction control, the target discharge amount is calculated by dividing the reservoir usage amount by the target discharge time set based on the road surface μ, and the calculated target discharge amount and the target rotation speed setting are calculated. Can be set based on the map.

Reference Signs List 1 vehicle brake fluid pressure control device 5 master cylinder 13 inlet valve 14 outlet valve 16 reservoir 17 pump 21 electric motor 21a eccentric cam 100 control unit FL, RR, RL, FR wheel brake

Claims (3)

An inlet valve interposed in a hydraulic path from a hydraulic source to a wheel brake, an outlet valve interposed in a hydraulic path from the wheel brake to a reservoir, and a hydraulic pressure from the reservoir to the hydraulic source A pump interposed in a road and driven by a motor having an eccentric cam; and anti-lock brake control and brake fluid stored in the reservoir by pressure reduction control of the anti-lock brake control. And a control unit for performing control to return to the source side, the vehicle brake fluid pressure control device,
The control unit includes:
Estimating the reservoir usage corresponding to the amount of increase from the initial state of the brake fluid in the reservoir,
A brake fluid pressure control device for a vehicle, characterized in that the motor is driven until the used amount of the reservoir becomes zero, and then the motor is further rotated by one rotation and then stopped.   2. The vehicle brake fluid pressure control device according to claim 1, wherein the control unit determines that the reservoir usage amount has become 0 when a predetermined time has elapsed from the end of the pressure reduction control. 3. The control unit includes:
In the pressure reduction control,
Based on the hydraulic pressure at the start of the pressure reduction control and the hydraulic pressure at the end of the pressure reduction control, estimating a consumed fluid amount corresponding to the amount of brake fluid flowing into the reservoir from the wheel brake,
Estimating the discharge amount corresponding to the amount of brake fluid discharged from the reservoir from the rotation speed of the motor,
3. The vehicle brake fluid pressure control device according to claim 1, wherein the reservoir use amount is obtained based on the discharge amount, the consumed liquid amount, and a previous value of the reservoir use amount. 4.

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