JP6475124B2 - Operation start current acquisition method - Google Patents

Description

  The present invention relates to acquisition of an operation start current of a solenoid valve.

Patent Document 1 includes (a) (a-1) a master cylinder in which a hydraulic pressure having a height based on the hydraulic pressure in a back chamber behind the pressurizing piston is generated in the pressurizing chamber in front of the pressurizing piston; (A-2) a back unit that is connected to the back chamber and that can control the fluid pressure in the back chamber; and (a-3) a first unit that includes a control device mainly composed of a computer; (B) a plurality of wheel cylinders of a plurality of hydraulic brakes provided corresponding to each of the plurality of wheels of the vehicle, operated by the hydraulic pressure of the pressurizing chamber, and suppressing rotation of the wheels; c) A hydraulic brake system including a second unit provided with a plurality of electromagnetic valves provided between each of the plurality of wheel cylinders and the pressurizing chamber is described. The back hydraulic pressure control device includes one or more solenoid valves.
As described above, since the first unit includes the control device and the like, the operation start current can be acquired in the first unit for the current valve included in the rear hydraulic pressure control device. However, since the control unit or the like is not included in the second unit, it is difficult to acquire the operation start current in the second unit for the electromagnetic valve included in the second unit.

JP2013-208987A

  The subject of this invention is acquiring the operation start electric current of the solenoid valve contained in a 2nd unit.

Means and effects for solving the problem

In the hydraulic brake system according to the present invention, the operation start current of the solenoid valve included in the second unit is acquired in a state where the first unit and the second unit are mounted on the vehicle and are connected to each other. .
Thus, if the first unit and the second unit are connected, the operation start current of the electromagnetic valve included in the second unit can be acquired using the control device included in the first unit.
In addition, when the operation start current of the electromagnetic valve included in the second unit is acquired, the constituent elements (for example, sensors) of the first unit can be used, so that the operation of the electromagnetic valve included in the second unit is performed. There is also an advantage that it is not necessary to use an external device (for example, a sensor or the like) to acquire the start current.
The operation of the solenoid valve means that the solenoid valve switches between the open state and the closed state, and the operation start current is supplied to the coil when it switches between the open state and the closed state. Current. The current supplied when switching from the open state to the closed state and the current supplied when switching from the closed state to the open state are not necessarily the same.

1 is a circuit diagram of a hydraulic brake system according to an embodiment of the present invention. In this hydraulic brake system, the operation start current according to an embodiment of the present invention is acquired. It is a figure which shows the periphery of brake ECU of the said hydraulic brake system. (a) It is sectional drawing of the holding valve which is a component of the said hydraulic brake system. (b) It is a figure which shows the operating characteristic of the holding valve of (a). (a) It is a figure which shows the change of the supply current at the time of acquiring the operation start current of the said holding valve. (b) It is a figure which shows the change state of the servo pressure at the time of acquiring the operation start electric current of the said holding valve, the hydraulic pressure of a pressurization chamber, and the hydraulic pressure of a wheel cylinder. It is a flowchart showing the operation characteristic acquisition program memorize | stored in the memory | storage part of the said brake ECU. It is a flowchart showing a part of the said operation characteristic acquisition program (S2). It is a flowchart showing another aspect of a part of the said operation characteristic acquisition program.

Embodiment of the Invention

  Hereinafter, a hydraulic brake system according to an embodiment of the present invention will be described in detail with reference to the drawings. In this hydraulic brake system, the operation start current acquisition method according to the embodiment of the present invention is implemented.

<Configuration of hydraulic brake system>
As shown in FIG. 1, the hydraulic brake system includes (i) hydraulic pressures provided on the brake cylinders 6FL and 6FR of the hydraulic brakes 4FL and 4FR provided on the left and right front wheels 2FL and 2FR and on the left and right rear wheels 8RL and 8RR. Brake cylinders 12RL, 12RR of the brakes 10RL, 10RR, (ii) a hydraulic pressure generator 14 capable of supplying hydraulic pressure to the brake cylinders 6FL, 6FR, 12RL, 12RR, (iii) the brake cylinders 6FL, 6FR, 12RL, 12RR And a slip control valve device 16 provided between the hydraulic pressure generator 14 and the hydraulic pressure generator 14. The hydraulic pressure generator 14, the slip control valve device 16, and the like are controlled by a brake ECU (Elecronic Control Unit) 18 (see FIG. 2) mainly composed of a computer.
In the present embodiment, the hydraulic pressure generating device 14 and the brake ECU 18 are unitized to be the first unit 20, and the slip control valve device 16 is unitized to be the second unit 22.

The hydraulic pressure generating device 14 includes (i) a master cylinder 26, (ii) a back hydraulic pressure control device 28 that controls the hydraulic pressure in the back chamber of the master cylinder 26, and the like.
The master cylinder 26 includes pressurizing pistons 32 and 34, an input piston 36, and the like that are liquid-tight and slidably fitted in series with each other in the housing 30.
The fronts of the pressurizing pistons 32 and 34 are the pressurizing chambers 40 and 42, respectively. Brake cylinders 6FL and 6FR for the left and right front wheels 2FL and 2FR are connected to the pressurizing chamber 40 via a fluid passage 44, and the brake cylinders 12RL for the left and right rear wheels 8RL and 8RR are connected to the pressurizing chamber 42 via a fluid passage 46. 12RR is connected. When hydraulic pressure is supplied to each of the brake cylinders 6FL, 6FR, 12RL, and 12RR, the hydraulic brakes 4FL, 4FR, 10RL, and 10RR are operated, and rotation of the wheels 2FL, 2FR, 8RL, and 8RR is suppressed.
Hereinafter, in the present specification, when it is not necessary to distinguish wheel positions for hydraulic brakes, FL, FR, RL, and RR indicating wheel positions may be omitted.
The pressurizing pistons 32 and 34 are urged in the backward direction by return springs 48 and 49, but the pressurizing chambers 40 and 42 are communicated with the reservoir 52 at the retracted end position.

The pressurizing piston 34 includes (a) a front piston portion 56 provided at the front portion, (b) an intermediate piston portion 58 provided at the intermediate portion and projecting in the radial direction, and (c) provided at the rear portion. A rear small diameter portion 60 having a smaller diameter than the piston portion 58 is included. The front piston portion 56 and the intermediate piston portion 58 are fitted into the housing 30 in a liquid-tight and slidable manner, the front of the front piston portion 56 is a pressurizing chamber 42, and the front of the intermediate piston portion 58 is an annular chamber. 62.
On the other hand, the housing 30 is provided with an annular inner peripheral projection 64, and the rear small-diameter portion 60 is fitted in a liquid-tight and slidable manner. As a result, a back chamber 66 is formed between the intermediate piston portion 58 and the inner peripheral projection 64 behind the intermediate piston portion 58.
The input piston 36 is located behind the pressurizing piston 34, and a space 70 is defined between the rear small diameter portion 60 and the input piston 36. A brake pedal 24 as a brake operation member is linked to the rear portion of the input piston 36 via an operating rod 72 and the like.

The annular chamber 62 and the separation chamber 70 are connected by a connecting passage 80, and a communication control valve 82 is provided in the connecting passage 80. The communication control valve 82 is a normally closed electromagnetic on-off valve. A stroke simulator 90 is connected to a portion of the connection passage 80 closer to the annular chamber 62 than the communication control valve 82 via a simulator passage 88. The simulator passage 88 and the reservoir 52 are connected by a reservoir passage 84, and a reservoir cutoff valve 86 is provided in the reservoir passage 84. The reservoir shut-off valve 86 is a normally open electromagnetic on-off valve.
In addition, a hydraulic pressure sensor 92 is provided in a portion closer to the annular chamber than the communication control valve 82 of the connection passage 80. The hydraulic pressure sensor 92 detects the hydraulic pressure in the annular chamber 62 and the separation chamber 70 in a state where the annular chamber 62 and the separation chamber 70 are communicated with each other and are disconnected from the reservoir 52. Since the hydraulic pressure in the annular chamber 62 and the separation chamber 70 has a height corresponding to the operating force of the brake pedal 24, the hydraulic pressure sensor 92 can be referred to as an operating hydraulic pressure sensor.

A back hydraulic pressure control device 28 is connected to the back chamber 66.
The back hydraulic pressure control device 28 includes (a) a high pressure source 96, (b) a regulator 98, (c) an input hydraulic pressure control unit 100, and the like.
The high-pressure source 96 is a pump device 106 having a pump 104 and a pump motor 105, an accumulator 108 that stores hydraulic fluid discharged from the pump device 106 in a pressurized state, and a hydraulic pressure of the hydraulic fluid stored in the accumulator 108. It includes an accumulator pressure sensor 109 that detects the accumulator pressure. The pump motor 105 is controlled so that the accumulator pressure detected by the accumulator pressure sensor 109 is maintained within the set range.

The regulator 98 includes (d) a housing 110, and (e) a pilot piston 112 and a control piston 114 provided in the housing 110 in a direction parallel to the axis L and arranged in series with each other. A high pressure chamber 116 is formed in front of the control piston 114 of the housing 110 and is connected to a high pressure source 96. A pilot pressure chamber 120 is provided between the pilot piston 112 and the housing 110, a control chamber 122 is provided behind the control piston 114, and a servo chamber 124 serving as an output chamber is provided in front of the control piston 114. A high pressure supply valve 126 is provided between the servo chamber 124 and the high pressure chamber 116. The high-pressure supply valve 126 is a normally closed valve, and always shuts off the servo chamber 124 and the high-pressure chamber 116.
A low pressure passage 128 extending in parallel with the axis L is formed at the center of the control piston 114 and is always in communication with the reservoir 52. The low pressure passage 128 opens at the front end of the control piston 114 and faces the high pressure supply valve 126. Therefore, when the control piston 114 is at the retracted end, the servo chamber 124 is disconnected from the high pressure chamber 116 and communicated with the reservoir 52 via the low pressure passage 128. When the control piston 114 is advanced, the servo chamber 124 is shut off from the reservoir 52 and the high pressure supply valve 126 is opened to communicate with the high pressure chamber 116. Reference numeral 130 denotes a spring that biases the control piston 114 in the backward direction.

The pilot pressure chamber 120 is connected to the liquid passage 46 via the pilot passage 152. Therefore, the hydraulic pressure of the pressurizing chamber 42 of the master cylinder 26 acts on the pilot piston 112.
Further, the back chamber 66 of the master cylinder 26 is connected to the servo chamber 124 via an output port 153 and a servo passage 154. Since the servo chamber 124 and the back chamber 66 are directly connected, the servo pressure that is the hydraulic pressure in the servo chamber 124 and the hydraulic pressure in the back chamber 66 are basically the same level. The servo pressure is detected by a servo pressure sensor 156 as a back surface hydraulic pressure detection device provided in the servo passage 154.
The input hydraulic pressure control unit 100 includes a pressure increasing linear valve (SLA) 160 and a pressure reducing linear valve (SLR) 162, and is connected to the control chamber 122. The pressure increasing linear valve 160 is provided between the control chamber 122 and the high pressure source 96, and the pressure reducing linear valve 162 is provided between the control chamber 122 and the reservoir 52. By controlling the supply current to the coil of the pressure-increasing linear valve 160 and the coil of the pressure-reduction linear valve 162 (hereinafter, the supply current to the coil may be simply referred to as supply current; the same applies to other solenoid valves). The hydraulic pressure in the control chamber 122 is controlled. In addition, a damper 164 is connected to the control chamber 122, and hydraulic fluid is exchanged between the control chamber 122 and the damper 164.

  In the present embodiment, a relationship determined based on the structure of the regulator 98 or the like is established between the hydraulic pressure in the control chamber 122 and the servo pressure that is the hydraulic pressure in the servo chamber 124. A relationship determined based on the structure of the master cylinder 26 and the like is established between the hydraulic pressures in the pressure chambers 40 and 42. The servo pressure has a height based on the hydraulic pressure in the control chamber 122, the hydraulic pressure in the pressurizing chambers 40 and 42 is the same as the hydraulic pressure in the rear chamber 66 (hereinafter, the hydraulic pressure in the rear chamber 66 is also referred to as servo pressure). In other words, the height is based on the hydraulic pressure of the control chamber 122.

  The slip control valve device 16 includes (i) holding valves 170FR, 170FL, pressure reducing valves 172FR, 172FL provided corresponding to the wheel cylinders 6FR, 6FL of the left and right front wheels 2FR, 2FL, (ii) left and right rear wheels 8RL, It includes holding valves 170RL, 170RR, pressure reducing valves 172RL, 172RR, etc. provided corresponding to each of the 8RR wheel cylinders 12RL, 12RR. The holding valves 170FR, 170FL, 170RL, and 170RR are provided between the pressurizing chambers 40 and 42 and each of the wheel cylinders 6FR, 6FL, 12RL, and 12RR, and the pressure reducing valves 172FR, 172FL, 172RL, and 172RR are the wheel cylinders 6FR. , 6FL, 12RL, 12RR and the decompression reservoirs 174F, R. The holding valve 170 is a normally open valve, and the pressure reducing valve 172 is a normally closed valve. The holding valve 170 and the pressure reducing valve 172 are each operated by controlling the current supplied to the coil. Be switched between.

As shown in FIG. 3A, the holding valve 170 includes a valve seat 180 formed in a housing 178, and a poppet valve portion 182 including a valve element 181 that can approach and separate from the valve seat 180; A coil 183, a plunger 184, a solenoid 186 provided with a spring 185, and the like. , 12 are connected.
In the holding valve 170, the elastic force Fs of the spring 185 acts in a direction to separate the valve element 181 from the valve seat 180. Further, when a current is supplied to the coil 183, an electromagnetic force Fd corresponding to the supplied current acts in a direction in which the valve element 181 approaches the valve seat 180. Further, when a hydraulic pressure is applied to the holding valve 170, a differential pressure which is a hydraulic pressure difference between the high pressure side and the low pressure side, for example, a hydraulic pressure in the pressurizing chambers 40, 42 and a hydraulic pressure in the wheel cylinders 4, 12 The differential pressure acting force Fp determined based on the difference acts on the direction in which the valve element 191 is separated from the valve seat 190.
The poppet valve portion 182 is opened and closed by the relationship between the above-described electromagnetic force Fd, the elastic force Fs of the spring 185, and the differential pressure acting force Fp, and the elastic force Fs of the spring 185 is considered to be substantially constant. As shown by the solid line in FIG. 3 (b), when the differential pressure acting force Fp is large, it is clear that the electromagnetic force Fd necessary for maintaining the closed state is larger than when the differential pressure acting force Fp is small. In other words, the holding valve 170 in the closed state is switched to the open state when the supply pressure is larger than when it is small when the differential pressure is large. The supply current when the electromagnetic valve is switched from the closed state to the open state can be referred to as a valve opening current as an operation start current.

As shown in FIG. 2, the brake ECU 18 is mainly composed of a computer and includes an execution unit 210, a storage unit 212, an input / output unit 214, and the like. The operation fluid pressure sensor 92, the accumulator pressure sensor 109, and the servo pressure sensor 156 are connected to the input / output unit 214, and a stroke for detecting the stroke of the brake pedal 24 (hereinafter sometimes referred to as an operation stroke). A sensor 200 and a wheel speed sensor 204 provided to correspond to each of the wheels 2 and 8 to detect the rotational speed of the wheel are connected, and a pump motor 105, a pressure increasing linear valve 160, a pressure reducing linear valve 162, The communication cutoff valve 82, the reservoir cutoff valve 86, the holding valve 170, the pressure reducing valve 172, and the like are connected via a drive circuit (not shown). The vehicle body speed is estimated based on the detection value of the wheel speed sensor 204, and the slip state of each of the wheels 2 and 8 is acquired.
The storage unit 212 stores a plurality of programs, tables, and the like, but the operation characteristic storage unit 216 stores operation characteristics of electromagnetic valves such as the holding valve 170.

<Acquisition of operating characteristics>
For each of the holding valves 170, the operating characteristic, which is the relationship between the valve opening current and the differential pressure between the hydraulic pressure on the high-pressure side and the hydraulic pressure on the low-pressure side when switching from the closed state to the open state, Before a vehicle equipped with a brake system is shipped, it is individually acquired and stored in the operation characteristic storage unit 216.
Each operating characteristic of the holding valve 170 does not necessarily become a standard operating characteristic indicated by a solid line in FIG. 3B due to manufacturing variation or the like. On the other hand, as described above, since the second unit 22 does not include the brake ECU 18 or the like, it is difficult to obtain the operating characteristics of the holding valve 170 in the second unit 22.
Therefore, the first unit 20 and the second unit 22 are assembled to the vehicle and a hydraulic brake system is configured, that is, the second unit 22 and the first unit 20 are connected, and the second unit 22 is connected to the second unit 22. With the wheel cylinders 6 and 12 connected, the operating characteristics of each of the holding valves 170 are individually acquired by the brake ECU 18 and the like. Hereinafter, one of the four holding valves 170FR, FL, RR, RL for which the operation characteristic is acquired is referred to as a target holding valve 170.

The operation characteristic acquisition program represented by the flowchart of FIG. 5 is executed when, for example, an operation characteristic acquisition command is output.
In step 1 (hereinafter abbreviated as S1. The same applies to other steps), the variable J for selecting the target holding valve is set to 1, and the holding valve corresponding to the variable 1 is set as the target holding valve 170. . For example, if a holding valve is associated with each variable J {(variable, holding valve) = (1,170FR), (2,170FL), (3,170RR), (4,170RL)}, target holding The valves 170 can be selected in a predetermined order (FR, FL, RR, RL). In S2, the operating characteristics are acquired and stored for the selected target holding valve 170. In S3, the variable J is incremented by 1. In S4, it is determined whether or not the variable J exceeds 4. When the variable J is 4 or less, S2 and S3 are repeatedly executed, and each of the four holding valves 170 is sequentially set as the target holding valve 170, and the operating characteristics are acquired. When the variable J becomes 5, the determination in S4 is YES and the program is terminated. The operating characteristics for each of the four holding valves 170 were acquired and stored.

The acquisition and storage of the operation characteristic of the target holding valve 170 in S2 includes the following steps.
(1) Differential pressure control process
(1-1) Downstream Fluid Pressure Control Process When the target holding valve 170 is open, the servo pressure is controlled so as to approach the first set pressure P1 (k). The hydraulic pressure of the wheel cylinders 6 and 12 is a height based on the first set pressure P1 (k).
(1-2) Upstream Fluid Pressure Control Process When a predetermined set current is supplied to the coil 183 of the target holding valve 170, it is switched to the closed state. Then, the servo pressure is controlled to be a second set pressure P2 (k) that is larger than the first set pressure P1 (k). The hydraulic pressure in the pressurizing chambers 40 and 42 becomes a height based on the second set pressure P2 (k).
The set current is kept at the closed state even when the maximum value Imax of the current value that can be supplied to the holding valve 170 or the maximum differential pressure acting force Fp that is expected when obtaining the operating characteristics is applied. For example, the current value Imax can be obtained.

The solid line in FIG. 4B indicates the actual servo pressure (detected value of the servo pressure sensor 156), the broken line indicates the temporary detected value of the hydraulic pressure in the pressurizing chambers 40, 42, and the alternate long and short dash line indicates the wheel cylinders 6, 12 The provisional detection value is shown. The provisional detection value is a detection value when it is assumed that a sensor for detecting the hydraulic pressure in the pressurizing chambers 40 and 42 and a sensor for detecting the hydraulic pressure in the wheel cylinders 6 and 12 are provided. As indicated by the broken line, the hydraulic pressure in the pressurizing chambers 40 and 42 is lower than the servo pressure, and as indicated by the alternate long and short dash line, the hydraulic pressure in the wheel cylinders 6 and 12 is approximately the pressurizing chamber 40 when the target holding valve 170 is open. , 42 is the same as the hydraulic pressure.
The actual differential pressure between the high-pressure side hydraulic pressure and the low-pressure side hydraulic pressure of the target holding valve 170 is approximately the magnitude obtained by subtracting the wheel cylinder hydraulic pressure from the hydraulic pressure in the pressurizing chambers 40, 42. It becomes ΔP * in FIG. On the other hand, the differential pressure ΔP (k) of the target holding valve 170 used for the operating characteristics is the difference between the detected values of the servo pressure sensor 156, that is, the second set pressure P2 (k) to the first set pressure P1 (k). The subtracted value {P2 (k) −P1 (k)}. The difference ΔP (k) in the detected values of the servo pressure sensors 156 and the actual differential pressure (the difference in provisional detected values) ΔP * of the target holding valve 170 are substantially the same as shown in FIG. 4B. {ΔP (k) ≈ΔP *}. Therefore, the differential pressure between the high pressure side and the low pressure side of the target holding valve 170 can be considered to be the set differential pressure ΔP (k) {= P2 (k) −P1 (k)}.

(2) Operation start current acquisition step In a state where the differential pressure of the target holding valve 170 is constant {set differential pressure ΔP (k)}, the supply current to the coil 183 is gradually decreased, and the target holding valve 170 is moved from the closed state. The supply current in the case of switching to the open state is acquired as the valve opening current.
In the present embodiment, the supply current to the coil 183 of the target holding valve 170 is decreased by ΔI, while the servo pressure is detected by the servo pressure sensor 156, and it is determined whether or not it has become smaller than the threshold value δth.
When the target holding valve 170 is switched from the closed state to the open state, the working fluid flows out from the pressurizing chamber to which the target holding valve 170 is connected to the hole cylinder, so that the pressurizing pistons 32 and 34 are advanced, and the rear chamber 66 is moved forward. The volume of the motor increases transiently and the servo pressure decreases transiently. On the other hand, when the servo pressure is lowered in the regulator 98, the control piston 114 is advanced and the high-pressure supply valve 126 is opened. However, due to the sliding resistance of the control piston 114, the elastic force of the spring 130, etc., the control piston 114 is not immediately advanced even if the servo pressure is lowered, and is advanced with a delay. Therefore, as indicated by the solid line in FIG. 4 (b), when the volume of the back chamber 66 becomes transiently large, the detection value of the servo pressure sensor 156 is decreased, and as a result, the target holding valve 170 is closed. It can be clearly seen that the state has been switched from the open state to the open state.

When the detection value by the servo pressure sensor 156 decreases by the threshold value δth or more, that is, the supply current to the coil 183 when the target holding valve 170 is switched from the closed state to the open state is acquired. This current is a valve opening current Iopen (k) as an operation start current. For the target holding valve 170, a set {ΔP (k), Iopen (k)} of differential pressure and valve opening current is acquired.
In this embodiment, the valve opening current Iopen (k) is a control command value when the servo pressure becomes smaller than the threshold value δth. On the other hand, a current monitor can be provided in the electric circuit including the coil 183, and the detected value of the current monitor when the servo pressure becomes smaller than the threshold value δth can be set as the valve opening current Iopen (k).
Further, the threshold value δth can be set to a magnitude that can be regarded as the target holding valve 170 being switched from the closed state to the open state.

Specifically, the acquisition and storage of the operation characteristic in S2 is executed by an operation characteristic acquisition routine represented by the flowchart of FIG. In this embodiment, the set differential pressure ΔP (k) is changed twice, and two sets of differential pressure and valve opening current {ΔP (k), Iopen (k)} are acquired. Although the operating characteristics are acquired based on two sets, the operating characteristics may be acquired based on more than two sets. In addition, when the operation characteristic is acquired for the target holding valve 170, it is assumed that the other three holding valves are in a closed state.
In S11, the count value k of the number counter for counting the number of times of acquiring the set of the differential pressure and the valve opening current is set to 1. The first set is acquired. In S12, the supply current to the coil 183 of the target holding valve 170 is set to 0, and the open state is set. If the target holding valve 170 is already open when S12 is executed, the open state is maintained as it is. Next, in S13 and 14, the servo pressure target value (hereinafter referred to as target servo pressure) is set to the first set pressure P1 (k) (k = 1), and the actual servo pressure is set to the first set pressure P1 ( The pressure increasing linear valve 160 and the pressure reducing linear valve 162 are controlled so as to approach 1). S13 and S14 are repeatedly executed until the detected value of the servo pressure sensor 156 reaches the first set pressure P1 (1).
When the detected value of the servo pressure sensor 156 is substantially equal to the first set pressure P1 (1) and the determination in S14 is YES, the set current Imax is supplied to the target holding valve 170 in S15 to be closed. In S16, the target servo pressure is set to the second set pressure P2 (k) (k = 1), and the servo pressure is increased by the pressure-increasing linear valve 160 and the pressure-decreasing linear valve 162. In S17, the detection value of the servo pressure sensor 156 is read, and it is determined whether or not the second set pressure P2 (1) has been reached. S16 and S17 are repeatedly executed until the servo pressure reaches the second set pressure P2 (1). When the servo pressure reaches the second set pressure P2 (1), the differential pressure between the high pressure side fluid pressure and the low pressure side fluid pressure of the target holding valve 170 is the set differential pressure ΔP (1) {= P2 (1) − P1 (1)}, and in S18, the pressure-increasing linear valve 160 and the pressure-reducing linear valve 162 are switched to the closed state.

  In S19, the supply current to the coil of the target holding valve 170 is reduced by the set current ΔI. In S20, the servo pressure is detected by the servo pressure sensor 156, and whether or not the detected value has become smaller than the threshold value δth. Is determined whether or not the detected value is equal to or lower than the set pressure {P2 (2) −δth}. When S19 and S20 are repeatedly executed and the servo pressure becomes smaller than the threshold value δth, the supply current Iopen (1) at that time is read in S21, and the first differential pressure and the valve opening current are Set {ΔP (1), Iopen (1)}.

Next, in S22, the count value k of the number counter is incremented by 1 and set to 2. In S23, it is determined whether or not the count value k is larger than a set count value N (for example, 2 can be set). If the count value k is equal to or smaller than the set count value, the determination is NO and S24 and subsequent steps are executed. . The second set is acquired.
In S24, the supply current to the target holding valve 170 is set to 0 and switched to the open state. In S25, the first (second) first set pressure P1 (2) is set to the previous (first) second set pressure P2 (1). In S26, the servo pressure is detected by the servo pressure sensor 156, and the servo is detected. It is determined whether or not the pressure has reached the current first set pressure P1 (2).
As shown in FIG. 4B, when the target holding valve 170 is switched to the open state, the hydraulic pressure of the wheel cylinder is the hydraulic pressure of the pressurizing chamber [previous second set pressure P2 (1) {= The height based on the first set pressure P1 (2)} is increased to substantially the same height. On the other hand, the servo pressure is returned to the previous second set pressure P2 (1) {= the current first set pressure P1 (2)} by the operation of the regulator 98. As shown in FIG. When the servo pressure reaches almost the same height as the first set pressure P1 (2) this time, it is estimated that the hydraulic pressure of the wheel cylinder has also reached the height based on the first set pressure P1 (2). be able to.
It is estimated that the hydraulic pressure of the wheel cylinder has reached the height based on the first set pressure P1 (2) after the set time has elapsed since the servo pressure reached the first set pressure P1 (2). You can also.

If the determination in S26 is YES, S15 and subsequent steps are executed.
After the supply current to the target holding valve 170 is set to the set current Imax in S15, the servo pressure is controlled to the second set pressure P2 (2) higher than the first set pressure P1 (2) in S16 and 17. . Here, the differential pressure between the high pressure side and the low pressure side of the holding valve 170 is set differential pressure ΔP (2) = P2 (2) −P1 (2), but the set differential pressure ΔP (2) is set differential pressure. The size is different from ΔP (1). In S18 to 20, the supply current to the coil 183 is gradually reduced with the supply current to the pressure-increasing linear valve 160 and the pressure-reducing linear valve 162 being zero, and the detected value of the servo pressure sensor 156 becomes the threshold value. It is detected whether or not it has become smaller than the value δth. A valve opening current Iopen (2), which is a supply current when the detected value becomes smaller than the threshold value δth, is acquired, and the second set of differential pressure and valve opening current {ΔP (2), Iopen (2 )} Is acquired. A total of two sets are acquired.

In S22, the count value k of the number counter is incremented by 1 and is set to 3. Therefore, the count value is larger than the set count value 2, and the determination in S23 is YES. In S27, the actual operating characteristics of the target holding valve 170 are acquired based on the two sets {ΔP (1), Iopen (1)}, {ΔP (2), Iopen (2)} (for example, FIG. 3). (operation characteristic indicated by a broken line in (b)) is stored in the operation characteristic storage unit 216.
In addition, after the operation characteristics are acquired, an end process is performed in S28. For example, the pressure increasing linear valve 160 is closed, the pressure reducing linear valve 162 is opened, and the target holding valve 170 is opened. The operating characteristics of one target holding valve 170 have been acquired.

  As described above, in this embodiment, the operating characteristic of the holding valve 170 is acquired in a state where the first unit 20 and the second unit 22 are assembled, and the brake ECU 18 included in the first unit 20 is installed. Obtained using. In addition, the second unit 22 alone cannot apply hydraulic pressure to the holding valve 170, but if the rear hydraulic pressure control device 28 and the master cylinder 26 of the first unit 20 are used, hydraulic pressure is applied to the holding valve 170. It becomes possible. Furthermore, it is possible to detect that the holding valve 170 has been switched from the closed state to the open state by using the servo pressure sensor 156 included in the first unit 20, and it is not necessary to use an external sensor or the like. There are also advantages.

<Operation in hydraulic brake system>
When the brake pedal 24 is depressed by the driver, a braking request is issued. In response to the braking request, the hydraulic brakes 4 and 10 are operated.
In the regulator 98, the hydraulic pressure in the control chamber 122 is increased by the control of the input hydraulic pressure control unit 100. As the control piston 114 advances, the servo chamber 124 is cut off from the reservoir 52 and communicated with the high-pressure chamber 116, and the servo pressure is supplied to the back chamber 66. In the master cylinder 26, the pressurizing piston 34 is advanced by the servo pressure, the hydraulic pressure is generated in the front pressurizing chambers 40, 42, supplied to the wheel cylinders 6, 12, and the hydraulic brakes 4, 10 are operated. Be made. The hydraulic pressure of the wheel cylinders 6 and 12 is controlled by the control of the input hydraulic pressure control unit 100.

During braking, when the braking slip of at least one of the wheels 2 and 8 becomes larger than the set slip value, or when the rotational deceleration becomes larger than the set deceleration, the tendency of the wheels to lock becomes stronger than the set level. In this case, anti-lock control is started.
In the anti-lock control, for example, the hydraulic pressures of the wheel cylinders 6 and 12 are individually controlled so that the slip state of the wheels is within an appropriate range determined by the friction coefficient of the road surface. Based on the rotational acceleration of the wheels 2 and 8, the braking slip state, etc., any one of the pressure reducing mode, the holding mode and the slow pressure increasing mode is selectively determined, and the holding valve 170 and the pressure reducing valve 172 are individually opened and closed accordingly. Be made. With respect to the holding valve 170, the supply current is controlled based on the operating characteristic stored in the operating characteristic storage unit 216, so that the opening / closing control of the holding valve 170 can be performed satisfactorily, and anti-lock control is performed. The control accuracy can be improved. Thereby, the braking distance can be shortened.

In the present embodiment, the brake ECU 18 or the like constitutes a control device, and an operation characteristic acquisition unit is configured by a part that stores the operation characteristic acquisition program represented by the flowchart of FIG.
Moreover, execution of S12-17 respond | corresponds to a differential pressure | voltage control process, execution of S12-14 corresponds to a downstream hydraulic pressure control process, and execution of S15-17 respond | corresponds to an upstream hydraulic pressure control process. Moreover, execution of S19-21 corresponds to an operation start current acquisition process.

Note that it is not indispensable that the current first set pressure P1 (k) is the previous second set pressure P2 (k-1). In that case, when the determination of S23 is NO, the process is returned to S12, and S12 to S23 are repeatedly executed so that a set of differential pressure and valve opening current can be acquired.
Further, in the above embodiment, the operation characteristics are sequentially acquired for each of the target holding valves 170, but the valve opening current Iopen (when the differential pressure is the set differential pressure ΔP (1) After 1) is acquired for each of the four holding valves, the valve opening current Iopen (2) when the differential pressure is the set differential pressure ΔP (2) is acquired for each of the four holding valves 170. It can also be made.
Furthermore, not only the holding valve 170 but also the pressure reducing valve 172 can acquire the operating characteristics in a state where the first unit 20 and the second unit 22 are assembled in the vehicle.

Further, when the first set of differential pressure and valve opening current is acquired, the first set pressure P1 (1) can be atmospheric pressure. When the hydraulic brake system remains in an inoperative state before the vehicle is shipped, no hydraulic pressure is generated in the wheel cylinders 6 and 12 (the hydraulic pressure in the wheel cylinders 6 and 12 is almost atmospheric pressure). ) Is normal. When the holding valve 170 is in the open state, the detected value of the servo pressure sensor 156 is equal to or lower than the set pressure, and the detected value of the stroke sensor 200 is equal to or lower than the set stroke, the pressurizing pistons 34 and 36 are It is presumed that the pressurizing chambers 40 and 42 are in the state of being connected to the reservoir 52 at the retracted end position. It can be estimated that the wheel cylinders 6 and 12 are in communication with the reservoir 52 via the pressurizing chambers 40 and 42, and the hydraulic pressure of the wheel cylinders 6 and 12 is atmospheric pressure. Further, when the state in which the wheel cylinders 6 and 12 are communicated with the reservoir 52 continues for a set time or longer, it can be estimated that the hydraulic pressure in the wheel cylinders 6 and 12 is atmospheric pressure.
The above set pressure is a value at which the servo pressure can be regarded as being at atmospheric pressure, and the set stroke is a value at which the brake pedal 24 can be regarded as being in the reverse end position. An example in that case will be described with reference to FIG.

In S31 and S32 of the flowchart of FIG. 7, when the target holding valve 170 is in the open state, the detection value of the servo pressure sensor 156 and the detection value of the stroke sensor 200 are acquired, the servo pressure is lower than the set pressure, and the stroke is set. It is determined whether or not it is smaller than the stroke, and it is determined whether or not the hydraulic pressure of the wheel cylinders 6 and 12 is at atmospheric pressure. When the servo pressure is lower than the set pressure and the pressurizing pistons 34 and 36 are in the retracted end position, it is estimated that the hydraulic pressure in the wheel cylinders 6 and 12 is at atmospheric pressure, and in S33, the first set pressure P1 ( 1) is atmospheric pressure.
Next, in S15, the target holding valve 170 is closed, and S16 to S23 are executed in the same manner as in the above embodiment. In this case, the differential pressure is set differential pressure ΔP (1) {= P2 (1) −P1 (1) = P2 (1)}.
Then, after the set of differential pressure and valve opening current {ΔP (1), Iopen (1)} is acquired, the count value k of the counter is incremented by 1, and in S24-26, Similarly, the target holding valve 170 is opened, and the hydraulic pressure of the wheel cylinder is changed to the first set pressure P1 (2) of the current time (second time) {the second set pressure P2 (1) of the previous time (first time). After reaching the height based on the same}, S15 to 21 are executed, and the valve opening current Iopen (2) in the case of the set differential pressure ΔP (2) is acquired. Based on this, the operating characteristics are obtained.

As described above, in this embodiment, it is not necessary to control the hydraulic pressure of the wheel cylinders 6 and 12 to the first set pressure P (1) when acquiring the first set. As a result, the time required to acquire the operating characteristics can be shortened.
In addition, this embodiment is desirably applied when the structure of the master cylinder 26 is such that the hydraulic pressure in the pressurizing chambers 40 and 42 and the hydraulic pressure in the back chamber 66 are substantially the same. When the hydraulic pressure of the wheel cylinder is atmospheric pressure, the differential pressure ΔP (k) that is the difference between the actual differential pressure ΔP * of the target holding valve 170 and the detected value of the servo pressure sensor 156 becomes substantially the same. is there.
As described above, in this embodiment, the execution of S31 to 33 and S15 to 17 corresponds to the differential pressure control process, the execution of S31 to 33 corresponds to the downstream hydraulic pressure estimation process, and the processes of S15 to 17 Execution corresponds to the upstream hydraulic pressure control process at the time of estimation.
In the present embodiment and the above embodiment, the value of the second set pressure P (1) may be the same or different.

  In addition, the regulator 98 may have a structure having a spool, and the structure of the back hydraulic pressure control device is not limited. The present invention can be variously modified based on the knowledge of those skilled in the art in addition to the above-described embodiments. It can be implemented in an improved manner.

  4, 10: Hydraulic brake 6, 12: Wheel cylinder 14: Hydraulic pressure generator 16: Slip control valve device 18: Brake ECU 40, 42: Pressurization chamber 66: Back chamber 156: Servo pressure sensor 170: Holding valve 183 : Coil 200: Stroke sensor 216: Operating characteristic storage unit

Patentable invention

(1) (i) a master cylinder in which a hydraulic pressure having a height based on a hydraulic pressure in a back chamber behind the pressurizing piston is generated in a pressurizing chamber in front of the pressurizing piston; and (ii) in the back chamber. A first unit including a rear hydraulic pressure control device connected and capable of controlling the hydraulic pressure in the rear chamber; and (iii) a control device mainly comprising a computer;
A plurality of wheel cylinders of a plurality of hydraulic brakes provided corresponding to each of the plurality of wheels of the vehicle, operated by the hydraulic pressure of the pressurizing chamber, and suppressing rotation of the wheels;
A hydraulic brake system including a second unit including a plurality of electromagnetic valves provided between each of the plurality of wheel cylinders and the pressurizing chamber,
Each of the plurality of solenoid valves is operated based on a differential pressure between a hydraulic pressure of the pressurizing chamber to which the solenoid valve is connected and a hydraulic pressure of the wheel cylinder, and a supply current. ,
The first unit includes a back hydraulic pressure detection device that detects a hydraulic pressure in the back chamber,
The control device operates with a relationship between the differential pressure at the start of operation and the supply current for each of the plurality of solenoid valves in a state where the first unit and the second unit are assembled to the vehicle. A hydraulic brake system comprising: an operation characteristic acquisition unit that acquires characteristics; and an operation characteristic storage unit that stores the operation characteristics acquired by the operation characteristic acquisition unit.
(2) The control device controls each of the plurality of solenoid valves to individually control the hydraulic pressures of the plurality of wheel cylinders, so that the slip state of each of the plurality of wheels is within an appropriate range. The hydraulic brake system according to item (1), including a slip control unit that controls
Examples of the slip control unit include an antilock control unit, a traction control unit, a vehicle stability control unit, and the like.
(3) In the state where the differential pressure for the target electromagnetic valve, which is the target electromagnetic valve for acquiring the operating characteristic of one of the plurality of electromagnetic valves, is the set differential pressure, While gradually changing the supply current to the target solenoid valve, the backside fluid pressure detection device detects the fluid pressure in the backside chamber, and when the detected backside chamber fluid pressure falls below a threshold value, The liquid according to item (1) or (2), including an operation start current acquisition unit that acquires a supply current to the target electromagnetic valve as an operation start current when the target electromagnetic valve is changed from the closed state to the open state. Pressure brake system.
The target electromagnetic valve may be a normally open valve or a normally closed valve. In the case of a normally open valve, the coil is closed by supplying a current to the coil, and the supplied current is gradually reduced. When the supply current is reduced to the operation start current determined by the set differential pressure, the target solenoid valve is switched to the open state. When the target solenoid valve is a normally closed valve, the current is not supplied to the coil and the coil is in the closed state. Therefore, the supply current to the coil is increased when the operating characteristics are acquired. When the supply current is increased to the operation start current determined by the set differential pressure, the target solenoid valve is switched to the open state.
(4) The downstream hydraulic pressure control unit that controls the hydraulic pressure in the back chamber to the first set pressure by controlling the back hydraulic pressure control device in the open state of the target solenoid valve. When,
And an upstream hydraulic pressure control unit that controls the hydraulic pressure in the back chamber to a second set pressure higher than the first set pressure by controlling the back hydraulic pressure control device in a closed state of the target electromagnetic valve. The hydraulic brake system according to any one of items (1) to (3).
Since a predetermined relationship is established between the hydraulic pressure in the back chamber and the hydraulic pressure in the pressurizing chamber, the hydraulic pressure in the pressurizing chamber becomes a height based on the hydraulic pressure in the back chamber. In addition, in the open state of the solenoid valve, the hydraulic pressure in the pressurizing chamber and the hydraulic pressure in the wheel cylinder are the same, so if the hydraulic pressure in the back chamber is controlled to the first set pressure, the hydraulic pressure in the wheel cylinder is The height is based on the first set pressure.
(5) The operation characteristic acquisition unit is configured such that the target electromagnetic valve is in an open state, the hydraulic pressure in the back chamber detected by the back hydraulic pressure detection device is equal to or lower than a set pressure that can be regarded as atmospheric pressure, and a brake operation A downstream hydraulic pressure estimation unit that estimates that the hydraulic pressure of the wheel cylinder connected to the target solenoid valve is at the atmospheric pressure when the stroke of the member is equal to or less than a set stroke;
When the wheel cylinder pressure estimating unit estimates that the wheel cylinder pressure is at atmospheric pressure, the back hydraulic pressure control device is controlled to be higher than the atmospheric pressure in the closed state of the target solenoid valve. The hydraulic brake system according to any one of items (1) to (3), including a hydraulic control unit on the upstream side.
The set stroke can be set to a value that allows the brake operation member to be regarded as being in the backward end position. When the target solenoid valve is in the open state, the hydraulic pressure in the back chamber is at atmospheric pressure, and the brake operation member is in the retracted end position, the pressurizing piston is in the retracted end position, and the wheel cylinder is open to the pressurizing chamber. Therefore, it can be estimated that the hydraulic pressure of the wheel cylinder is almost atmospheric pressure. In addition, when the state in which the wheel cylinder is communicated with the reservoir continues for a set time or longer, the hydraulic pressure of the wheel cylinder can be estimated to be almost atmospheric pressure.

(6) The pressurizing chamber of the master cylinder in which a hydraulic pressure of a height based on the hydraulic pressure of the rear chamber behind the pressurizing piston is generated in the pressurizing chamber in front of the pressurizing piston, and the rotation of the wheel is suppressed. Solenoid valve provided between a hydraulic brake wheel cylinder and operated based on a current supplied to the coil and a differential pressure between the hydraulic pressure in the pressurizing chamber and the hydraulic pressure in the wheel cylinder An operation start current acquisition method for acquiring an operation start current of
A differential pressure control step of controlling the differential pressure between the hydraulic pressure of the pressurizing chamber and the hydraulic pressure of the wheel cylinder to a set differential pressure;
While gradually changing the supply current to the solenoid valve, the fluid pressure in the back chamber is detected, and the supply current to the coil of the solenoid valve at the time when the detected fluid pressure in the back chamber decreases by a threshold value or more The operation start current acquisition method characterized by including the operation start current acquisition process of acquiring as an operation start current of the above-mentioned electromagnetic valve.
This operation start current acquisition method can be implemented in the hydraulic brake system described in any one of (1) to (5).
(7) In the open state of the electromagnetic valve, the differential pressure control step includes a downstream hydraulic pressure control step of controlling the hydraulic pressure in the back chamber to a first set pressure, and the electromagnetic valve is closed, An upstream side hydraulic pressure control step of controlling the hydraulic pressure in the chamber to a second set pressure higher than the first set pressure.
(8) In the differential pressure control step, the hydraulic pressure of the wheel cylinder is estimated to be atmospheric pressure in the downstream hydraulic pressure estimation step for estimating the hydraulic pressure of the wheel cylinder and the downstream hydraulic pressure estimation step. And an estimated upstream hydraulic pressure control step for controlling the hydraulic pressure in the back chamber to a hydraulic pressure higher than the atmospheric pressure by closing the solenoid valve. Acquisition method.

Claims (1)

The pressurizing chamber of the master cylinder in which a hydraulic pressure of a height based on the hydraulic pressure of the back chamber behind the pressurizing piston is generated in the pressurizing chamber in front of the pressurizing piston, and the hydraulic pressure for suppressing the rotation of the wheel Start of operation of an electromagnetic valve provided between a brake wheel cylinder and operated based on a current supplied to the coil and a differential pressure between the hydraulic pressure in the pressurizing chamber and the hydraulic pressure in the wheel cylinder An operation start current acquisition method for acquiring current,
A differential pressure control step of controlling the differential pressure between the hydraulic pressure of the pressurizing chamber and the hydraulic pressure of the wheel cylinder to a set differential pressure;
While gradually changing the supply current to the solenoid valve, the fluid pressure in the back chamber is detected, and the supply current to the coil of the solenoid valve at the time when the detected fluid pressure in the back chamber decreases by a threshold value or more a look including the operation starting current acquisition step of acquiring the operation starting current of the solenoid valve,
When the differential pressure control process estimates that the hydraulic pressure of the wheel cylinder is atmospheric pressure in the downstream hydraulic pressure estimation process for estimating the hydraulic pressure of the wheel cylinder and the downstream hydraulic pressure estimation process. And an estimated upstream hydraulic pressure control step of controlling the hydraulic pressure in the back chamber to a hydraulic pressure higher than the atmospheric pressure with the electromagnetic valve closed .

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