JP4075102B2 - Vehicle brake control device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a vehicle brake control device, and more particularly to a brake control device having a stroke simulator function that gives a driver a feeling of brake operation in a pseudo manner when a brake pedal is depressed.
[0002]
[Prior art]
Conventionally, what gives a driver a feeling of brake operation in a pseudo manner during a brake operation is generally known as a stroke simulator. A model equipped with this stroke simulator function has a spring attached directly to the brake pedal in order to eliminate the hardness of the brake pedal entering when the brake is operated, and it is electrically connected to the wheel cylinder of the vehicle according to the operating force of the brake pedal. For example, DE 1961309 discloses a device that operates a solenoid valve of a braking force control device so as to increase or decrease the brake pressure to give a pseudo brake operation feeling and brake each wheel. Yes. In JP-A-63-64858, a solenoid valve is provided between the master cylinder and the wheel cylinder provided on the wheel, and the communication between the master cylinder and the wheel cylinder and the master cylinder and the absorber is controlled by the solenoid valve. An apparatus for selectively switching the communication state between the master cylinder and the absorber by means of a solenoid valve is disclosed.
[0003]
[Problems to be solved by the present invention]
However, in the case of using a spring for the brake pedal as described in the above publication, only a certain brake operation feeling is obtained by the urging force of the spring provided on the brake pedal in the brake pressure control, and the master cylinder The device that switches the communication between the absorber and the absorber by the solenoid valve, when performing the operation of switching the solenoid valve, the master cylinder and the wheel cylinder communicate with each other, so that only a certain brake operation feeling with one absorber can be obtained, The brake operation feeling according to the situation of the vehicle and the driver's preference could not be obtained.
[0004]
Therefore, the present invention has been made in view of the above-described problems, and an object of the present invention is to provide a brake control device that gives a feeling of brake operation in accordance with vehicle conditions and driver preference.
[0005]
[Means for Solving the Problems]
The first technical means taken in order to solve the above problems includes a sensor for detecting a vehicle state or a brake operation state, and a first and a second sensor arranged in series with the brake operation member and responsive to the brake operation member. A second elastic body, and a stroke of the brake operation member by the urging force of the first and second elastic bodies from the start of operation of the brake operation member until a signal from the sensor reaches a predetermined condition, The signal from became a predetermined condition sometimes The brake operation member is caused to stroke by the urging force of only one of the first and second elastic bodies.
[0006]
With the above configuration, when the brake operation member is normally operated, the brake operation feeling is obtained by the first and second elastic bodies arranged in series with the brake operation member, and the signal from the sensor is in a predetermined condition. Since the brake operation member can be stroked by the urging force of only one of the first and second elastic bodies, the brake operation feeling is switched under a predetermined condition.
[0007]
The second technical means includes a sensor for detecting a vehicle state or a brake operation state, and a brake operation member. Against A first elastic body and a second elastic body arranged in series and responding to the brake operating member, and at least one of the first and second elastic bodies are arranged and a piston responding to the brake operating member is arranged inside. A provided cylinder, a reservoir for releasing brake fluid from the cylinder, a solenoid valve disposed between the reservoir and the cylinder, and a control device for controlling the solenoid valve based on a signal from the sensor; The control device comprises From the start of operation of the brake operation member until the signal from the sensor reaches a predetermined condition, the brake operation member is stroked by the biasing force of the first and second elastic bodies, and the signal from the sensor becomes the predetermined condition. After The solenoid valve is operated when a signal from the sensor is in a predetermined condition. The The brake operation member is caused to stroke by the biasing force of only one of the first and second elastic bodies.
[0008]
With the above configuration, the brake operation member usually strokes by the urging force of the first and second elastic bodies, and when it reaches a predetermined condition, the brake operation member comes to stroke only by the urging force of one of the elastic bodies. Under predetermined conditions, it is possible to change the feeling of brake operation and give a feeling of brake operation according to the vehicle situation and the driver's preference.
[0009]
In the above case, if the first elastic body is disposed in the piston, the apparatus becomes small in the axial direction, and the apparatus can be miniaturized.
[0010]
The third technical means includes a sensor that detects a vehicle state or a brake operation state, a first elastic body that responds to a brake operation member, a master cylinder that is provided in series with the first elastic body, and the master cylinder A first elastic absorber that stores the brake fluid from the first elastic absorber and returns the brake fluid to the master cylinder side by an urging force of the second elastic body, and the first elastic absorber and An electromagnetic valve disposed between the master cylinders, and a control device that controls the electromagnetic valve based on a signal from the sensor. The control device receives a signal from the sensor from the start of operation of the brake operation member. Until the predetermined condition is reached, the brake operating member is stroked by the urging force of the first and second elastic bodies, and the signal from the sensor becomes the predetermined condition. sometimes The electromagnetic valve is operated and the brake operation member is caused to stroke by the biasing force of only the first elastic body.
[0011]
With the above configuration, the brake operation member normally strokes by the urging force of the first and second elastic bodies, and when the predetermined condition is met, the brake operation member strokes by the urging force of only the first elastic body, so that the brake operation feeling is It changes, and it becomes possible to give the feeling of brake operation according to a driver | operator's liking. In this case, it can be realized with a simple configuration using a master cylinder.
[0012]
According to a fourth technical means, a sensor for detecting a vehicle state or a brake operation state, a first elastic body that responds to the brake operation member, and a piston that responds to the brake operation member are disposed inside. A cylinder for releasing brake fluid from the cylinder, a solenoid valve disposed between the reservoir and the cylinder, a master cylinder provided in series with the first elastic body, and the master cylinder A first elastic absorber for storing the brake fluid and having a second elastic body therein and returning the brake fluid to the master cylinder side by the urging force of the second elastic body, and a signal from the sensor for the electromagnetic valve The control device controls the first and second bullets from the start of operation of the brake operation member until the signal from the sensor reaches a predetermined condition. The brake operating member is stroked by the urging force of the body, the signal from the sensor reaches a predetermined condition sometimes The electromagnetic valve is actuated to stroke the brake operation member by the urging force of only the second elastic body.
[0013]
With the above configuration, the brake operation member normally strokes by the urging force of the first and second elastic bodies, and when the predetermined condition is met, the brake operation member strokes by the urging force of only the second elastic body, so that the brake operation feeling is Instead, it is possible to give a feeling of brake operation according to the vehicle situation and the driver's preference. In this case, it can be easily realized by a combination of the second and third technical means.
[0014]
A fifth technical means includes a sensor that detects a vehicle state or a brake operation state, a master cylinder that responds to a brake operation member, stores brake fluid from the master cylinder, and has a first elastic body therein. A first elastic absorber for returning brake fluid to the master cylinder side by the urging force of the first elastic body; and storing the brake fluid from the master cylinder and having a second elastic body therein. A second elastic absorber that returns the brake fluid to the master cylinder side by the biasing force of the first electromagnetic absorber, an electromagnetic valve disposed between the first elastic absorber and the master cylinder, and the electromagnetic valve as a signal from the sensor And a control device that controls based on the biasing forces of the first and second elastic bodies from the start of operation of the brake operation member until the signal from the sensor reaches a predetermined condition. The brake operating member is stroked, the signal from the sensor reaches a predetermined condition sometimes The electromagnetic valve is actuated to stroke the brake operation member by the urging force of only the second elastic body.
[0015]
With the above configuration, the brake operation member normally strokes by the urging force of the first and second elastic bodies, and when the predetermined condition is met, the brake operation member strokes by the urging force of only the second elastic body, so that the brake operation feeling is Instead, it is possible to give a feeling of brake operation according to the vehicle situation and the driver's preference. In this case, the first and second elastic absorbers may be connected to the master cylinder and the flow path of the first elastic absorber may be blocked, and a master cylinder normally provided in the vehicle may be used instead of the cylinder. The configuration is simple.
[0016]
The sixth technical means includes a sensor for detecting a vehicle state or a brake operation state, a master cylinder provided in series with the brake operation member and having first and second hydraulic chambers, and brake fluid from the first hydraulic chambers. A first elastic absorber having a first elastic body therein and returning brake fluid to the master cylinder side by the biasing force of the first elastic body, and storing brake fluid from the second hydraulic chamber A second elastic body having a second elastic body therein and returning brake fluid to the master cylinder side by the urging force of the second elastic body, and disposed between the first elastic absorber and the first hydraulic chamber. An electromagnetic valve provided, and a control device that controls the electromagnetic valve based on a signal from the sensor, the control device from the start of operation of the brake operation member until the signal from the sensor becomes a predetermined condition Is the first and The brake operating member is stroked by the urging force of the second elastic body, the signal from the sensor reaches a predetermined condition sometimes The electromagnetic valve is actuated to stroke the brake operation member by the urging force of only the second elastic body.
[0017]
With the above configuration, the brake operation member normally strokes by the urging force of the first and second elastic bodies, and when the predetermined condition is met, the brake operation member strokes by the urging force of only the second elastic body, so that the brake operation feeling is It changes, and it becomes possible to give the feeling of brake operation according to a driver | operator's liking. In this case, it is only necessary to connect the first and second elastic absorbers to a master cylinder having two hydraulic chambers and shut off the flow path of the first elastic absorber, so that the configuration is simple.
[0018]
Preferably, if the sensor is any one of a pedal force sensor, a stroke sensor, a rudder angle sensor, a pressure sensor, and a wheel speed sensor, the operation force related to the brake operation in the case of the pedal force sensor, and the brake operation in the case of the stroke sensor In the case of a steering angle sensor, the amount of steering is known. In the case of a pressure sensor, the pressure applied to the wheel cylinder or the master cylinder is known. In the case of a vehicle speed sensor, the vehicle speed is known. Can be detected accurately.
[0019]
Further, if a mode switch is further provided and the switching timing of the solenoid valve is changed according to the mode set by the mode switch, it is possible to give a free brake operation feeling according to the driver's preference.
[0020]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
[0021]
FIG. 1 shows a first embodiment of a simulator 1 for a vehicle brake control device of the present invention. As shown in FIG. 1, the vehicle has a rudder angle sensor that detects the rudder angle, a treading force sensor that detects the depressing force of the brake pedal 2, and a stroke sensor that detects the depressing speed from the depressing amount or depressing amount of the brake pedal 2. A pressure sensor for detecting a pressure of a wheel cylinder provided on the wheel, a sensor 20 for detecting a vehicle speed, such as a wheel speed sensor, a cylinder 5 in which the piston 6 is slidable inside, The second elastic bodies 4 and 8, the electromagnetic valve 10, the reservoir 9, and the control device 38 are provided.
[0022]
The rod 3, the first elastic body 4 and the second elastic body 8 connected to the brake pedal 2 are arranged in series, and the piston 6 in the cylinder 5 slides in the second elastic body 8 and the volume changes. It is provided in the hydraulic chamber 7 in the cylinder space to be disposed, and is arranged to urge the piston 6 to the initial state. In addition, an atmospheric pressure reservoir 9 for releasing brake fluid from a discharge port provided in the hydraulic chamber 7 of the cylinder 5 is provided outside, and a normally open electromagnetic is provided between the reservoir 9 and the hydraulic chamber 7 of the cylinder 5. A valve 10 is interposed, and a control device 38 is provided to control the electromagnetic valve 10 based on a signal from the sensor 20.
[0023]
Next, a brake control device using the stroke simulator 1 will be described with reference to the system configuration diagram of FIG. This apparatus is a combination of the stroke simulator 1 shown in FIG. The braking force control device 42 is provided independently of the stroke simulator 1 here, but is not limited thereto.
[0024]
The stroke simulator 1 is provided with a steering angle sensor for detecting a steering angle on the steering wheel 17 in order to accurately detect a vehicle state or a brake operation state, a pedal force sensor 22 and a stroke sensor 23 are provided on the brake pedal 2, and Is provided with a mode switch 26 that can vary the brake operation feeling according to the driver's setting, and these signals are input to the control device 38. The control device 38 energizes (turns on) the solenoid valve 10 when a signal from the sensor is in a predetermined condition described later, and strokes the brake pedal 2 by the urging force of only the first elastic body 4. .
[0025]
Further, the braking force control device 42 is configured as shown in FIG. 2, and supplies brake fluid to a wheel cylinder 31 (only one wheel is shown here) provided on each wheel, thereby braking the wheel. Is now working. When the pressure drops below a certain level due to a signal state from the pressure sensor 39, the brake fluid is supplied by driving the motor 35 and pumping the brake fluid from the reservoir 36 by the pump 34 by the pressure accumulated in the accumulator 37. Is called. When the brake is operated on the wheel cylinder 31, the brake pressure is supplied by turning on the normally closed control valve 32 with the pressure accumulated in the accumulator 37. Further, when the brake pressure of the wheel cylinder 31 is reduced, the brake control can be performed by releasing the brake pressure to the reservoir 36 by turning on the normally closed control valve 33. The control valves 32 and 33 that perform the brake control and the motor 35 that drives the pump 34 detect the vehicle state and the brake operation state by the sensors 21, 22, 23, 24, 25, 26, and 39, and the signals Based on the above, it is controlled by the signal of the output port of the control device 38.
[0026]
Next, processing of the brake control device including the stroke simulator 1 and the braking force control device 42 will be described based on the flowchart of FIG.
[0027]
When a vehicle key is inserted into an ignition switch (not shown), the ignition switch is turned on, and power is supplied to the control device 38 from a battery (not shown), first, initial processing is executed in step S101. . In this initial process, the memory in the control device 38 is cleared, and an initial value is substituted into the RAM. Thereafter, the program starts the main routine in a predetermined time in step S102. For example, the main routine is executed in 6 ms here, but it is not limited to this time. In the next step S103, input processing is performed, and signals from switches and sensors such as the control switch 26, the rudder angle sensor 21, the treading force sensor 22, the stroke sensor 23, the pressure sensor 24, and the wheel speed sensor 25 are transmitted to the control device 38. The data is input to the input port of the computer and read by the microcomputer. In step S104, the stroke simulator process shown in FIGS. 5 to 13 is performed. In step S105, the target wheel cylinder (W / C) pressure is calculated. In this target W / C pressure calculation, the target W / C pressure with respect to the depression force applied to the brake pedal 2 is obtained from a predetermined map, and then the process proceeds to step S106. In step S106, the actual signal obtained from the pressure sensor 24 provided on the wheel cylinder side, that is, the actual W / C pressure (actual W / C pressure) is obtained from the map in step S105. It is determined whether or not the pressure is equal to the target W / C pressure. If the actual W / C pressure is equal to the target W / C pressure, the process returns to step S102; otherwise, step S107 is performed. In the next step S107, it is determined whether or not the actual W / C pressure is greater than the target W / C pressure. If the actual W / C pressure is greater than the target W / C pressure, the pressure reducing control valve (pressure reducing SOL) 33 is turned on in step S108. If the actual W / C pressure (actual W / C pressure) is smaller than the target W / C pressure obtained from the map, the pressure increase control valve (pressure increase SOL) 32 is turned on in step S109. The control valves 32 and 33 for pressure increase and pressure reduction are determined so as to optimize the on-time based on the deviation between the actual W / C pressure and the target W / C pressure. Such brake control is performed from step S102 to step S109. Repeat the process.
[0028]
Next, five examples of the stroke simulator process shown in step S104 of FIG. 4 will be described here.
[0029]
・ Stroke simulator process (1) (See Fig. 5)
A first example is shown. In step S201, the brake pedal 2 is depressed and the process is determined by a change in the state of a stop switch (not shown). This stop switch is turned off when the brake pedal is not depressed, and is turned on when the brake pedal is depressed. The stop switch is mounted in the vicinity of the brake pedal of the vehicle, and its signal is input to the input port of the control device 38. Yes.
[0030]
If the brake pedal 2 is not operated in step S201, nothing is performed in this process. However, when the brake pedal 2 is depressed, the stop switch is switched from OFF to ON, and the process proceeds to step S202. If the brake pedal 2 is continuously depressed, the process proceeds to step S203. In step S202, a stroke simulator control pedaling force calculation is executed. As shown in FIG. 6, this calculation obtains the stroke simulator control pedal force with respect to the vehicle speed obtained from the signal from the wheel speed sensor 25 attached to the wheel, and is preset by a map. Here, the control pedaling force SSPDLF corresponding to the vehicle speed is obtained. In step S203, the actual pedaling force from the pedaling force sensor 22 is compared with the pedaling force SSPDLF obtained from the map. When the actual pedaling force value is larger than the pedaling force SSPDLF obtained from the map, the stroke simulator SOL10 is turned on in step S204. This process ends. In other cases, the stroke simulator SOL10 is turned off and this process is terminated.
[0031]
By performing such processing, the pedaling force characteristic can be changed from an arbitrary position of the pedal stroke as shown in FIG. 3 when the pedaling force is larger than the control pedaling force obtained from the vehicle speed. In addition, it is possible to make an appropriate brake operation feeling according to the vehicle speed.
[0032]
・ Stroke simulator process (2) (see Fig. 7)
A second example is shown. In step S301, it is determined whether the brake pedal 2 has been depressed. Here, when the brake pedal 2 is not depressed, the process proceeds to step S309, where an initial value is set for the control stroke in step S309, and the process is terminated. However, when the brake pedal 2 is depressed and the stop switch is turned on, a signal (pedal stroke) from the stroke sensor 23 is determined in step S302. Here, it is determined whether the pedal stroke from the actual sensor is greater than a predetermined value TH1, and if it is greater, step S303 is executed, but if not, this process ends. In the next step S303, the current value calculation of the stroke simulator control stroke is performed to obtain the current value SSPDLS. The pedal speed is obtained by dividing the signal change amount from the stroke sensor 23 shown in FIG. 8 for each predetermined period by the calculation time, and the pedal speed obtained in this way is obtained by mapping to the control stroke SSPDLS. In step S304, it is determined whether or not the current SSPDLS value obtained in step S303 is smaller than the previous value SSPDLS. If the current value is smaller than the previous value, the current value is substituted into SSPDLS in step S305 and the SSPDLS. Is updated, and the process proceeds to step S306. By updating SSPDLS in this way, this value becomes the previous value the next time this process is executed. On the other hand, if the current value is greater than or equal to the previous value, the process proceeds to step S306. In this step S306, the actual sensor value from the stroke sensor 23 is compared with SSPDLS. If the value from the sensor is larger, the stroke simulator SOL10 is turned on and this process is terminated. Otherwise, the stroke simulator SOL10 is turned off and this process is terminated.
[0033]
By performing such processing, the pedaling force characteristic can be changed from an arbitrary position of the pedal stroke as shown in FIG. 3 when the pedal stroke is larger than the control stroke obtained from the pedal speed, that is, as shown in FIG. Therefore, it is possible to make an appropriate brake operation feeling according to the pedal speed.
[0034]
・ Stroke simulator process (3) (See Fig. 9)
A third example is shown. In step S401, a road surface friction coefficient (road surface μ) is determined. In this μ determination, a vehicle speed is estimated from a wheel speed sensor 25 provided on each wheel, and a drop level of each wheel speed is determined from the estimated vehicle speed when the brake is operated, so that a road surface μ that is currently traveling is low μ, Whether it is classified as medium μ or high μ is required. In step S402, a stroke simulator control pedaling force calculation is performed to obtain a control pedaling force SSPDLF. As shown in FIG. 10, the control pedal force corresponding to the road surface μ obtained in step S401 is set in advance by a map, and the control pedal force corresponding to the road surface μ is obtained. In step S403, it is compared whether or not the actual pedaling force by the pedaling force sensor 22 is larger than the control pedaling force SSPDLF obtained from the map. If so, the stroke simulator SOL10 is turned on in step S404 and the process is terminated. In this case, the stroke simulator SOL10 is turned off in step S405, and this process ends.
[0035]
By performing such a process, a predetermined condition, that is, control in which the pedaling force is obtained from the road surface μ Pedal force Since the pedaling force characteristic can be changed from an arbitrary position of the pedal stroke as shown in FIG. 3 when it becomes larger than that, an appropriate brake operation feeling corresponding to the road surface μ can be created.
[0036]
・ Stroke simulator process (4) (See Fig. 11)
A fourth example is shown. In step S501, it is determined whether or not the brake pedal 2 has been depressed. If the brake pedal 2 is depressed, the stop switch is turned on and the process proceeds to step S503. If the brake pedal 2 is not depressed, the process proceeds to step S502. In step S502, a stroke simulator control pedal force calculation is performed to obtain a control pedal force SSPDLF. In this calculation, as shown in FIG. 12, the brake characteristics can be changed depending on the setting state of the mode switch 26. The mode switch 26 can be switched in multiple stages. Here, the brake operation feeling is switched in four stages. That is, here, the control pedal force SSPDLF is obtained from the state of the mode switch 26 by associating the control pedal force shown in FIG. 12 with a predetermined map. Thereafter, in step S503, the actual pedaling force from the pedaling force sensor 22 is compared with the control pedaling force SSPDLF obtained from the map. If the pedaling force from the sensor is larger than that obtained from the map, the stroke simulator 10 is turned on in step S504. If this is not the case, the stroke simulator 10 is turned off in step S505, and the process ends.
[0037]
By performing such processing, a predetermined condition, that is, control in which the pedaling force is obtained from the set position of the mode switch 26. Pedal force When it becomes larger, the pedaling force characteristic can be changed from an arbitrary position of the pedal stroke as shown in FIG. 3, so that it is possible to create an appropriate brake operation feeling according to the driver's preference.
[0038]
・ Stroke simulator process (5) (see Fig. 13)
A fifth example is shown. In step S601, it is determined whether brake pressure control (for example, anti-skid control, stability control, etc.) is in operation. If such control is being performed, the stroke simulator SOL10 is turned on in step S602. The process is terminated, but when the control is not performed, the stroke simulator SOL10 is turned off and the process is terminated.
[0039]
Next, another embodiment of the stroke simulator 1 will be described with reference to FIGS. 14 to 18.
[0040]
By performing such processing, the pedaling force characteristic can be changed from an arbitrary position of the pedal stroke as shown in FIG. 3 in a predetermined condition, that is, when brake pressure control is performed. A proper brake operation feeling can be created.
[0041]
Second embodiment (see FIG. 14)
A rod 3 is attached to the brake pedal 2, and one end of the first elastic body 4 is attached to the rod 3. In addition, a piston 61 is disposed inside the cylinder 51 so as to be slidable inside the cylinder. The piston 61 has a concave shape inside, and the other end of the first elastic body 4 is locked in the concave portion. ing. A hydraulic chamber 71 is formed inside the cylinder 51 and the piston 61. The hydraulic chamber 71 is in series with the first elastic body 4 and urges the piston 6 to an initial position (a position where the brake pedal 2 is not depressed). A second elastic body is disposed on the surface. The hydraulic chamber 71 is connected to the reservoir 9 via a discharge port through which the brake fluid is released to the outside of the piston 51 by the movement of the piston 61 that responds to the brake pedal 2. Further, a normally-open stroke simulator SOL (hereinafter referred to as an electromagnetic valve) 10 is interposed between the discharge port of the cylinder 51 and the reservoir 9, and receives a signal from the sensor 20 that detects the vehicle state by the control device 38. The solenoid valve 10 is switched. With such a configuration, the first elastic body 4 is disposed in the recess 62 of the piston 61 of the cylinder 51. Thus, since the 1st elastic body 4 is arrange | positioned in the recessed part 62 of piston 61, the stroke simulator 1 can be made small in an axial direction.
[0042]
The operation will be described. Normally, in the brake operation in which the electromagnetic valve 10 is off, the brake pedal 2 is stroked by the urging force of the first elastic body 4 and the second elastic body 8, but when the electromagnetic valve 10 is turned on under a predetermined condition, the reservoir Since the flow path to 9 is blocked, the volume of the hydraulic chamber 71 does not change, and the sliding of the piston 61 stops and the brake pedal 2 strokes by the biasing force of only the first elastic body 4. In addition, it is possible to arbitrarily change the timing for turning on the electromagnetic valve 10 when a predetermined condition is satisfied, thereby changing the brake characteristics.
[0043]
Third embodiment (see FIG. 15)
A rod 3 is attached to the brake pedal 2, and one end of the first elastic body 4 is attached to the rod 3. The other end of the rod 3 is connected to the piston of the master cylinder. A first elastic absorber 11 is provided that absorbs the brake fluid from the hydraulic chamber 14 whose volume is changed by sliding of the piston of the master cylinder 13 through the discharge port and returns the brake fluid to the master cylinder side. When the brake fluid is supplied, the first elastic absorber 11 is stored and a second elastic body 81 is provided therein, and acts to return the brake fluid to the master cylinder side by the urging force of the second elastic body 81. . In addition, a normally open electromagnetic valve 10 is interposed between the master cylinder 13 and the first elastic absorber 11. The electromagnetic valve 10 receives a signal from the sensor 20 that detects the vehicle state and is switched by the control device 38. When the brake pedal 2 is depressed in this configuration, a spring is also provided in the master cylinder 13 when the solenoid valve 10 is off. However, since this spring has a weak biasing force, the first elastic body 4 is mainly used. When the brake pedal 2 is operated, the urging force of the second elastic body 81 provides a feeling of brake operation. Therefore, when the electromagnetic valve 10 is turned on, the flow path through which the brake fluid flows to the first elastic absorber 11 is blocked, so that the volume change of the hydraulic chamber 14 in the master cylinder 13 does not occur. Therefore, in this case, the urging force of only the first elastic body 4 becomes a brake operation feeling. As described above, the brake characteristics can be changed by changing the timing for turning on the electromagnetic valve 10 according to a predetermined condition.
[0044]
-4th Embodiment (refer FIG. 16)
A rod 3 is attached to the brake pedal 2, and the master cylinder 13 is disposed in series with the cylinder 51. A piston 6 connected to the rod 3 is disposed inside the cylinder 51, and the piston 6 can slide in the cylinder. A first elastic body 41 is biased in the cylinder so as to return the brake pedal 2 to the initial position. The end of the first elastic body 41 is connected to the piston of the master cylinder 13, and when the brake pedal 2 is depressed, the piston 6 in the cylinder and the piston in the master cylinder move in conjunction with each other. A reservoir 9 for releasing brake fluid is connected from the hydraulic chamber 71 of the cylinder 51, and a normally-open electromagnetic valve 10 is disposed therebetween. The first elastic absorber 11 is connected to a hydraulic chamber whose volume is changed by the piston of the master cylinder 13. The first elastic absorber 11 stores the brake fluid therein and has a second elastic member 81 therein, and returns the brake fluid to the master cylinder side by the urging force of the second elastic member 81.
[0045]
The electromagnetic valve 10 is switched by the control device 38 in response to a signal from the sensor 20 that detects the vehicle state. In this configuration, when the brake pedal 2 is depressed, the spring in the master cylinder 13 has a weak biasing force when the solenoid valve 10 is off, so that the biasing force mainly from the first elastic body 41 and the second elastic body 81 is the brake operation. A feeling. Therefore, when the solenoid valve 10 is turned on, the flow path of the brake fluid to the reservoir 9 is blocked, so that the volume of the hydraulic chamber 71 in the cylinder 51 does not change. In this case, the second elastic body A biasing force of only 81 provides a feeling of brake operation. As described above, the brake characteristics can be changed by changing the timing for turning on the electromagnetic valve 10 according to a predetermined condition.
[0046]
-5th Embodiment (refer FIG. 17)
A rod 3 is attached to the brake pedal 2, and the rod 3 is connected to the piston of the master cylinder 13. Brake fluid is stored from the hydraulic chamber 14 of the master cylinder 13 through a discharge port, and the first elastic absorption member 42 has a first elastic body 42 therein and returns the brake fluid to the master cylinder side by the biasing force of the first elastic body. A body 11 is provided. There is also provided a second elastic absorber 16 for storing brake fluid from the master cylinder 14 and having a second elastic body 82 therein and returning the brake fluid to the master cylinder side by the urging force of the second elastic body 82. . An electromagnetic valve 10 is interposed between the master cylinder 13 and the first elastic absorber 11, and this electromagnetic valve 10 receives a signal from the sensor 20 for detecting the vehicle state and is switched by the control device 38. Yes.
[0047]
When the brake pedal 2 is stepped on in this configuration, the spring in the master cylinder 13 has a weak biasing force when the solenoid valve 10 is off. Therefore, the biasing force by the first elastic body 42 and the second elastic body 82 is mainly used for the brake operation. A feeling. When the solenoid valve 10 is turned on from this state, the flow path through which the brake fluid flows to the first elastic absorber 11 is blocked, and the urging force of only the second elastic body 82 provides a feeling of brake operation. Thus, the brake characteristics can be changed depending on the timing when the solenoid valve 10 is turned on.
[0048]
-6th Embodiment (refer FIG. 18)
A rod 3 is attached to the brake pedal 2, and the rod 3 is connected to a piston on the first hydraulic chamber side of the master cylinder 15 having first and second hydraulic chambers formed by a piston. The brake fluid is stored from the first hydraulic chamber 18 of the master cylinder 15 through the discharge port, and the first elastic body 42 is provided therein, and the brake pressure is returned to the master cylinder side by the urging force of the first elastic body 42. One elastic absorber 11 is provided. A second elastic absorber 16 is provided from the second hydraulic chamber 19 through the discharge port. The second elastic absorber 16 stores the brake fluid and has a second elastic body 82 therein, and acts to return the brake fluid to the master cylinder side by the urging force of the second elastic body 82. Further, an electromagnetic valve 10 is interposed between the first hydraulic chamber 18 of the master cylinder 15 and the first elastic absorber 11, and this electromagnetic valve 10 receives a signal from a sensor 20 that detects the vehicle state, It is switched by the control device 38.
[0049]
When the brake pedal 2 is stepped on in this configuration, the spring in the master cylinder 13 has a weak biasing force when the solenoid valve 10 is off, and the biasing force mainly from the first elastic body 42 and the second elastic body 82 is the brake operation feeling. It becomes. When the electromagnetic valve 10 is turned on in this state, the flow path through which the brake fluid flows to the first elastic absorber 11 is blocked, and the urging force of only the second elastic body 82 becomes a brake operation feeling. Thus, the brake characteristics can be changed depending on the timing when the solenoid valve 10 is turned on.
[0050]
In addition, it is also possible to provide a check valve that bypasses the electromagnetic valve 10 in parallel with the electromagnetic valve 10 shown in FIGS. 1 and 14 to 18 described above. This check valve function prevents the return of the brake pedal 2 from being delayed due to a delay in response of the solenoid valve 10 when the brake pedal 2 is suddenly returned with the solenoid valve 10 turned on. .
[0051]
【effect】
According to the first aspect of the present invention, the sensor includes a sensor that detects a vehicle state or a brake operation state, and first and second elastic bodies that are arranged in series with the brake operation member and respond to the brake operation member. When the signal from the sensor is in a predetermined condition, the brake operation member is stroked by the urging force of only one of the first and second elastic bodies. Brake operation feeling is obtained by the urging force of the first and second elastic bodies arranged in series with each other. When the signal from the sensor is in a predetermined condition, the urging force of only one of the first or second elastic body is obtained. Since the brake operation member can be stroked, the brake operation feeling is switched under a predetermined condition.
[0052]
According to the second invention, the sensor for detecting the vehicle state or the brake operation state, the first and second elastic bodies arranged in series with the brake operation member and responsive to the brake operation member, the first and first (2) A cylinder in which at least one of the elastic bodies is disposed and a piston responsive to the brake operation member is disposed inside, a reservoir for releasing brake fluid from the cylinder, and a reservoir disposed between the reservoir and the cylinder. An electromagnetic valve provided, and a control device that controls the electromagnetic valve based on a signal from the sensor, and the control device operates the electromagnetic valve when a signal from the sensor is in a predetermined condition, Since the brake operation member is stroked by the urging force of only one of the first or second elastic body, the brake operation member is normally urged by the first and second elastic bodies. When the specified condition is met, the stroke is caused by the urging force of only one of the elastic bodies, so the brake operation feeling is changed under the specified condition, and the brake according to the vehicle situation and the driver's preference An operational feeling can be given.
[0053]
According to the third invention, since the first elastic body is disposed in the piston, the apparatus is small in the axial direction, and the apparatus can be miniaturized.
[0054]
According to the fourth aspect of the invention, the sensor for detecting the vehicle state or the brake operation state, the first elastic body responsive to the brake operation member, the master cylinder provided in series with the first elastic body, and the master cylinder A first elastic absorber that stores the brake fluid from the first elastic absorber and returns the brake fluid to the master cylinder side by an urging force of the second elastic body, and the first elastic absorber and A solenoid valve disposed between the master cylinders, and a control device that controls the solenoid valve based on a signal from the sensor, wherein the control device is configured to control the solenoid valve when a signal from the sensor is in a predetermined condition. And the brake operating member is normally stroked by the urging forces of the first and second elastic bodies. When the predetermined condition is met, the stroke is made only by the urging force of the first elastic body, so that the brake operation feeling changes, and it becomes possible to give the brake operation feeling according to the vehicle situation and the driver's preference. This can be realized with a simple configuration using a cylinder.
[0055]
According to the fifth invention, the sensor for detecting the vehicle state or the brake operation state, the first elastic body that responds to the brake operation member, and the piston that responds to the brake operation member are disposed inside. A cylinder for releasing brake fluid from the cylinder, a solenoid valve disposed between the reservoir and the cylinder, a master cylinder provided in series with the first elastic body, and the master cylinder A first elastic absorber that stores the brake fluid and returns the brake fluid to the master cylinder side by the biasing force of only the second elastic body, and the solenoid valve from the sensor. A control device that controls based on the signal, and the control device operates the electromagnetic valve when the signal from the sensor is in a predetermined condition, and is based on the urging force of only the second elastic body. Since the brake operating member is caused to stroke, the brake operating member normally strokes by the urging force of the first and second elastic bodies, and when the predetermined condition is met, the stroke is struck by the urging force of only the second elastic body. Thus, the feeling of brake operation changes, and it becomes possible to give a feeling of brake operation according to the vehicle situation and the driver's preference. In this case, it can be easily realized from the combination of the second and fourth inventions.
[0056]
According to the sixth aspect of the invention, the sensor that detects the vehicle state or the brake operation state, the master cylinder that responds to the brake operation member, the brake fluid from the master cylinder is stored, and the first elastic body is provided inside. A first elastic absorber for returning brake fluid to the master cylinder side by the urging force of the first elastic body; and storing the brake fluid from the master cylinder and having a second elastic body therein. A second elastic absorber that returns the brake fluid to the master cylinder side by the biasing force of the first electromagnetic absorber, an electromagnetic valve disposed between the first elastic absorber and the master cylinder, and the electromagnetic valve as a signal from the sensor And a control device for controlling the brake operation member by operating the electromagnetic valve when a signal from the sensor is in a predetermined condition and applying a biasing force of the second elastic body. Since the brake operation member normally strokes due to the urging force of the first and second elastic bodies, and the stroke is only caused by the urging force of the second elastic body when a predetermined condition is met, A feeling of operation changes, and it becomes possible to give a feeling of brake operation according to the situation of the vehicle and the driver's preference. In this case, the first and second elastic absorbers may be connected to the master cylinder and the flow path of the first elastic absorber may be blocked, and a master cylinder normally provided in the vehicle may be used instead of the cylinder. The configuration is simple.
[0057]
According to the seventh invention, a sensor for detecting a vehicle state or a brake operation state, a master cylinder provided in series with a brake operation member and having first and second hydraulic chambers, and brake fluid from the first hydraulic chambers A first elastic absorber having a first elastic body therein and returning brake fluid to the master cylinder side by the biasing force of the first elastic body, and storing brake fluid from the second hydraulic chamber A second elastic body having a second elastic body therein and returning brake fluid to the master cylinder side by the urging force of the second elastic body, and disposed between the first elastic absorber and the first hydraulic chamber. An electromagnetic valve provided, and a control device that controls the electromagnetic valve based on a signal from the sensor, the control device operates the electromagnetic valve when a signal from the sensor is in a predetermined condition, and Attaching only the second elastic body Since the brake operating member is caused to stroke by force, the brake operating member is stroked by the urging force of the first and second elastic bodies, and when the predetermined condition is met, the stroke is born by the urging force of only the second elastic body. Thus, the feeling of brake operation changes, and it becomes possible to give a feeling of brake operation according to the vehicle situation and the driver's preference. In this case, it is only necessary to connect the first and second elastic absorbers to a master cylinder having two hydraulic chambers and shut off the flow path of the first elastic absorber, so that the configuration is simple.
[0058]
According to the eighth aspect of the present invention, the sensor is any one of a pedal force sensor, a stroke sensor, a rudder angle sensor, a pressure sensor, and a wheel speed sensor. The speed of the brake operation in the case, the steering amount in the case of the rudder angle sensor, the pressure applied to the wheel cylinder or the master cylinder in the case of the pressure sensor, the wheel speed of the vehicle in the case of the vehicle speed sensor, The vehicle state can be accurately detected.
[0059]
According to the ninth aspect of the present invention, a mode switch is further provided, and by changing the switching timing of the solenoid valve according to the mode set by the mode switch, it is possible to give a feeling of brake operation according to the driver's preference. .
[Brief description of the drawings]
FIG. 1 is a stroke simulator of a vehicle brake control device according to a first embodiment of the present invention.
FIG. 2 is a system configuration diagram of the vehicle brake control device according to the first embodiment of the present invention.
FIG. 3 is a diagram showing a relationship between pedal stroke and pedaling force.
FIG. 4 is a flowchart of a main routine showing processing of the vehicle brake control device of the present invention.
FIG. 5 is a flowchart showing a first example of stroke simulator processing shown in FIG. 4;
FIG. 6 is a diagram showing vehicle speed and stroke simulator control pedaling force in the processing of the vehicle brake control device of the present invention.
FIG. 7 is a flowchart showing a second example of the stroke simulator process shown in FIG. 4;
FIG. 8 is a diagram showing pedal speed and stroke simulator control stroke in the processing of the vehicle brake control device of the present invention.
FIG. 9 is a flowchart showing a third example of the stroke simulator process shown in FIG. 4;
FIG. 10 is a diagram showing road surface μ and stroke simulator control pedal force in the processing of the vehicle brake control device of the present invention.
FIG. 11 is a flowchart showing a fourth example of the stroke simulator process shown in FIG. 4;
FIG. 12 is a diagram showing a mode switch and a stroke simulator control pedal force in the processing of the vehicle brake control device of the present invention.
FIG. 13 is a flowchart showing a fifth example of the stroke simulator process shown in FIG. 4;
FIG. 14 is a stroke simulator of a vehicle brake control device according to a second embodiment of the present invention.
FIG. 15 is a stroke simulator of a vehicle brake control device according to a third embodiment of the present invention.
FIG. 16 is a stroke simulator of a vehicle brake control device according to a fourth embodiment of the present invention.
FIG. 17 is a stroke simulator of a vehicle brake control device according to a fifth embodiment of the present invention.
FIG. 18 is a stroke simulator of a vehicle brake control device according to a sixth embodiment of the present invention.
[Explanation of symbols]
1 Stroke simulator
2 Brake pedal (brake operating member)
3 Rod
4, 41, 42 First elastic body
5 cylinders
6,61 piston
7,71 Hydraulic chamber
8, 81, 82 Second elastic body
9 Reservoir
10 Solenoid valve (stroke simulator SOL)
11 First elastic absorber
13, 15 Master cylinder
14 Hydraulic chamber
16 Second elastic absorber
18, 19 First hydraulic chamber, second hydraulic chamber
20, 21, 22, 23, 24, 25 sensors
26 Mode switch
38 Control device

Claims (9)

A sensor for detecting a vehicle state or a brake operation state; and first and second elastic bodies arranged in series with the brake operation member and responsive to the brake operation member. The brake operation member is stroked by the urging force of the first and second elastic bodies until the signal from the first and second elastic bodies reaches a predetermined condition, and the first and second elastic bodies when the signal from the sensor satisfies the predetermined condition. A vehicle brake control device characterized in that the brake operation member is stroked by only one of the urging forces.   A sensor for detecting a vehicle state or a brake operation state; a first and second elastic body arranged in series with the brake operation member and responsive to the brake operation member; and at least one of the first and second elastic bodies A cylinder in which a piston responsive to the brake operation member is disposed, a reservoir for releasing brake fluid in the cylinder, an electromagnetic valve disposed between the reservoir and the cylinder, And a control device that controls the electromagnetic valve based on a signal from the sensor. The control device is configured to perform first and second operations from a start of operation of the brake operation member until a signal from the sensor becomes a predetermined condition. One of the first and second elastic bodies is operated by stroking the brake operation member by the urging force of the elastic body and operating the electromagnetic valve when a signal from the sensor is in a predetermined condition. Vehicle brake control device, characterized in that for the stroke of the brake operating member by Minozuke force.   The vehicle brake control device according to claim 2, wherein the first elastic body is disposed in the piston. A sensor for detecting a vehicle state or a brake operation state, a first elastic body responsive to a brake operation member, a master cylinder provided in series with the first elastic body, and storing brake fluid from the master cylinder A first elastic absorber having a second elastic body therein and returning brake fluid to the master cylinder side by the urging force of the second elastic body, and disposed between the first elastic absorber and the master cylinder An electromagnetic valve; and a control device that controls the electromagnetic valve based on a signal from the sensor, the control device from the start of operation of the brake operation member until the signal from the sensor reaches a predetermined condition. the brake operating member is stroked by the urging force of the first and second elastic bodies, said actuates the solenoid valve energization of only the first elastic member when the signal from the sensor reaches a predetermined condition Vehicle brake control device, characterized in that for the stroke of the brake operating member by. A sensor for detecting a vehicle state or a brake operation state, a first elastic body that responds to the brake operation member, and a piston that is internally disposed to respond to the brake operation member; A reservoir for releasing brake fluid, a solenoid valve disposed between the reservoir and the cylinder, a master cylinder provided in series with the first elastic body, and storing brake fluid from the master cylinder A first elastic absorber that returns the brake fluid to the master cylinder side by the urging force of the second elastic body, and a control device that controls the electromagnetic valve based on a signal from the sensor; The control device includes a biasing force of the first and second elastic bodies from the start of operation of the brake operation member until a signal from the sensor reaches a predetermined condition. Rk in the operating member is stroke, the vehicle signal from the sensor and wherein the thereby stroke the brake operating member by the urging force of actuates the solenoid valve only the second elastic member when a predetermined condition Brake control device. A sensor for detecting a vehicle state or a brake operation state, a master cylinder that responds to a brake operation member, a brake fluid from the master cylinder, and a first elastic body inside, and an urging force of the first elastic body The first elastic absorber for returning the brake fluid to the master cylinder side, the brake fluid from the master cylinder is stored, the second elastic body is provided inside, and the brake fluid is supplied by the urging force of the second elastic body. A second elastic absorber that returns to the master cylinder; an electromagnetic valve disposed between the first elastic absorber and the master cylinder; and a control device that controls the electromagnetic valve based on a signal from the sensor. The control device moves the brake operation member by the urging force of the first and second elastic bodies from the start of operation of the brake operation member until the signal from the sensor becomes a predetermined condition. Is stroke, the vehicle brake control device a signal and wherein the thereby stroke the brake operating member by the urging force of only the second elastic member by operating the solenoid valve when a predetermined condition from the sensor. A sensor that detects a vehicle state or a brake operation state, a master cylinder that is provided in series with the brake operation member and has first and second hydraulic chambers, stores brake fluid from the first hydraulic chamber, and has a first inside. A first elastic absorber having an elastic body and returning brake fluid to the master cylinder side by the urging force of the first elastic body; storing brake fluid from the second hydraulic chamber; A second elastic absorber for returning brake fluid to the master cylinder side by the urging force of the second elastic body, an electromagnetic valve disposed between the first elastic absorber and the first hydraulic chamber, A control device that controls the electromagnetic valve based on a signal from the sensor, and the control device includes first and second elastic bodies from the start of operation of the brake operation member until the signal from the sensor reaches a predetermined condition. To the power of Ri vehicle brake operating member is stroke, the signal from the sensor and wherein the thereby stroke the brake operating member by the urging force of only the second elastic member by operating the solenoid valve when a predetermined condition Brake control device.   The vehicle brake control device according to any one of claims 1 to 7, wherein the sensor is any one of a pedaling force sensor, a stroke sensor, a rudder angle sensor, a pressure sensor, and a wheel speed sensor.   The vehicle brake control device according to any one of claims 1 to 8, further comprising a mode switch, wherein the switching timing of the solenoid valve is changed according to a mode set by the mode switch.

Images