JP3888772B2 - Brake control device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a brake control device that executes brake fluid pressure control of a rear wheel to prevent the rear wheel from locking during braking.
[0002]
[Prior art]
During braking, the wheel load on the front wheel increases and the wheel load on the rear wheel decreases, so the rear wheel lock tendency becomes stronger than the front wheel. Therefore, in order to prevent such a rear wheel from being locked, a machine provided in the middle of the brake pipe to the rear wheel as a device that supplies lower brake fluid pressure to the rear wheel than the front wheel during braking. Proportioning valves of the formula are known.
[0003]
Further, in recent years, in automobiles, the mounting rate of brake control devices that execute ABS control for preventing wheel lock during braking is increasing. It is also known from, for example, Japanese Patent Application Laid-Open No. 5-278585 that the brake control device using the brake unit capable of executing the ABS control controls the same function as the above-described proportioning valve. .
[0004]
The apparatus described in this publication includes a wheel speed sensor that detects the rotational speed of the front wheels and the rotational speed of the rear wheels, an actuator that can adjust the brake hydraulic pressure of the rear wheels, and a control means that controls the operation of the actuator. The control means executes the braking force distribution control and the ABS control, and at the time of the braking force distribution control, when it is determined that the rotational speed of the rear wheel is smaller than a predetermined speed than the rotational speed of the front wheel, The brake fluid pressure of the rear wheel is reduced or maintained, and on the other hand, when it is determined that the rotation speed of the rear wheel is higher than the rotation speed of the front wheel, the brake fluid pressure of the rear wheel is restored. .
[0005]
Therefore, in this apparatus, the brake fluid pressure of the rear wheel is controlled so that the rotation speed of the rear wheel is lower than the rotation speed of the front wheel, that is, the rear wheel does not tend to lock more strongly than the front wheel. In addition, this brake control device has a feature that the proportioning valve can be eliminated by using a brake control control device capable of executing ABS control.
[0006]
[Problems to be solved by the invention]
By the way, when the applicant conducted a scrutiny and research, when the braking force distribution control is executed, the pressure increase amount when the wheel cylinder pressure of the rear wheel is increased (return pressure) is the pressure increase amount of normal ABS control or the sudden braking. It is suitable for the braking force distribution control to set the pressure more slowly than the pressure increase amount. That is, sudden pressure increase or decrease during normal brake operation leads to deterioration of sound vibration and pedal feeling, which gives the driver unpleasant feeling.
[0007]
However, when the slow pressure increase control is performed in this way, the traveling road surface changes from a low friction coefficient road (hereinafter referred to as a low μ road) to a high friction coefficient road (hereinafter referred to as a high μ road). When the wheel load of the rear wheel turning inner wheel generated when the vehicle shifts from turning to straight running, the rear wheel lock may occur even if the brake fluid pressure increase amount of the rear wheel is increased. In spite of this, there is a possibility that a sufficient braking force cannot be obtained by continuing the moderate pressure increase.
[0008]
The present invention has been made paying attention to the above-described problems, and in a brake control device that executes a braking force distribution control that operates a brake unit so as to suppress an excessive brake fluid pressure of a rear wheel during braking. In order to prevent the driver from feeling uncomfortable at the time of braking force distribution control, it is configured to increase the pressure gently when the pressure is increased (return pressure). The purpose is to improve the control quality by obtaining a sufficient braking force in response to a change in the rear wheel so that the wheel lock does not occur even if the power is increased.
[0009]
[Means for Solving the Problems]
In order to achieve the above-described object, the present invention is configured such that the brake fluid pressure of the wheel cylinder a that brakes each wheel of the vehicle can be suppressed independently as shown in the claim correspondence diagram of FIG. Based on the difference between the brake unit b, the wheel speed sensor c that detects the rotational speed of each wheel, and the rotational speed of the front wheel and the rotational speed of the rear wheel, the increase of the brake fluid pressure of the rear wheel is suppressed as necessary. Braking force distribution control means d configured to be able to execute braking force distribution control for operating the brake unit b so as to cause the braking force distribution control means d to adjust the rotational speed of the front wheels. A first boost suppression threshold that is lower than a reference value formed based on the first boost suppression threshold and a second boost suppression threshold set between the first boost suppression threshold and the reference value are set. Rotational speed is first increased When lower than the suppression threshold, execution of the braking force distribution control is started, and the rotation speed of the rear wheel is between the first pressure increase suppression threshold and the second pressure increase suppression threshold, and the second pressure increase suppression threshold and the reference The boost suppression state is configured to be switched between the case and the value. In addition, When the rotational speed of the rear wheel is between the first pressure increase suppression threshold and the second pressure increase suppression threshold, the braking force distribution control means d performs a slight pressure increase process for slightly increasing the brake fluid pressure of the rear wheel. If it is between the second pressure increase suppression threshold and the reference value, a slow pressure increasing process for increasing the pressure by a larger pressure increase amount than in the case of the slight pressure increasing process is performed. It is characterized by . Claims 2 As in the invention according to claim 2, in the brake control device according to claim 2, the braking force distribution control means d is in a state where the rotational speed of the rear wheels does not decrease as much as necessary even if the slow pressure increasing process is performed for a predetermined time. In some cases, it is preferable to perform a pressure increasing process for increasing pressure with a larger pressure increasing amount. Claims 3 As in the invention described in claim 2 In the described brake control apparatus, it is preferable that the pressure increasing process after the slow pressure increasing process in the braking force distribution control unit d ends the braking force distribution control. Claims 4 As described above, the braking force distribution control means d performs braking force distribution control based on the rotational acceleration of the rear wheels in addition to the rotational speed difference between the front and rear wheels, and the absolute value of the rotational acceleration is When the rotation speed is within a predetermined range including 0, in the first zone where the rotational speed of the rear wheel is larger than the first pressure increase suppression threshold, switching between the slow pressure increase process, the slight pressure increase process, and the pressure increase process is performed according to the conditions. In the second zone where the rotation speed is smaller than the first pressure increase suppression threshold, the holding process and the pressure reducing process are switched according to the conditions, and the holding process is performed in the third zone where the rotational acceleration is lower than the first zone and the second zone. And a rapid pressure increasing process is performed in the fourth zone where the rotational acceleration is higher than that in the first zone and the second zone, and the pressure increasing switching in the first zone is performed. 3 any one It is preferable to apply the described switching.
[0010]
(Operation) In the present invention, at the time of braking, the braking force distribution control means compares the rotational speed of the rear wheel with each boost suppression threshold, and if the rotational speed of the rear wheel is lower than the first boost suppression threshold by the braking force. Then, the execution of the braking force distribution control is started, and the increase of the brake fluid pressure of the rear wheel is suppressed to prevent the rear wheel from being locked. Then, in executing this braking force distribution control, the braking force distribution control means restores the rotational speed of the rear wheel once lowered and is higher than the first pressure increase suppression threshold, but still exceeds the second pressure increase suppression threshold. The boost suppression state is switched between when the braking force is low and when the braking force tends to be insufficient after returning to a value higher than the second boost suppression threshold. That is, when the former braking force is sufficient, the boost suppression is continued, but when the latter braking force tends to be insufficient, the boost suppression state is switched such that the boost suppression is weakened. This makes it possible to determine whether the braking force is excessive or insufficient, and increase the pressure accordingly, even if control with reduced pressure and increased pressure is performed so that the driver does not feel uncomfortable during braking force distribution control. By switching the suppression state, the braking force can be prevented from being insufficient. Also In the braking force distribution control, when the rotation speed of the rear wheel is between the first pressure increase suppression threshold and the second pressure increase suppression threshold, a slight pressure increase process is performed to slightly increase the brake fluid pressure of the rear wheel, On the other hand, when the rotational speed of the rear wheel returns to a value higher than the second pressure increase suppression threshold and the difference from the front wheel becomes smaller and the braking force tends to be insufficient, a gentle pressure increase process is performed. The pressure is increased by a pressure increase amount larger than that at the time of processing, that is, the pressure increase suppression is weakened. Claim 2 In the described invention, when the rotation speed of the rear wheel returns to a value higher than the second pressure increase suppression threshold and the difference from the front wheel becomes small and the braking force tends to be insufficient, first, the slow pressure increasing process is performed. However, when this slow pressure increasing process is performed for a predetermined time, when the rotational speed of the rear wheel is not reduced as much as necessary, a pressure increasing process with a larger pressure increase amount than the slow pressure increasing process is performed. High braking force can be obtained. In addition, as this pressure increasing process, the claim 3 As described, the process includes the process of instantaneously supplying the same brake fluid pressure as that of the front wheel side by terminating the braking force distribution control and completely removing the pressure increase suppression.
[0011]
Claim 4 In the described invention, at the time of braking force distribution control, in the fourth zone where the rotational acceleration of the rear wheels is larger than a predetermined value, that is, in an acceleration traveling state exceeding a predetermined value, sudden pressure increase processing, that is, pressure increase suppression is not performed. In the third zone in which the rotational acceleration of the wheel is smaller than a predetermined value, that is, in a sudden deceleration state that is greater than or equal to the predetermined value, the holding process is performed to suppress the pressure increase, and In the case of the slow deceleration that is within, in the second zone where the rotation speed of the rear wheel is lowered to a value lower than the first pressure increase suppression threshold and the lock tendency is strong, the holding process or the pressure reduction is performed according to the driving condition. In the case of the first zone in which the rotation speed of the rear wheel is larger than the first pressure increase suppression threshold value, the pressure increase suppression process, the slight pressure increase process, and the pressure increase are performed according to the driving conditions. Processing switching A. In the switching between the slow pressure increasing process, the slight pressure increasing process, and the pressure increasing process in the first zone, a switching determination based on at least the second pressure increase suppression threshold is performed.
[0012]
The rapid pressure increase control means a state where pressure can be increased, that is, if the master cylinder pressure is increased, it is transmitted to the wheel cylinder as it is.
[0013]
DETAILED DESCRIPTION OF THE INVENTION
Embodiments of the present invention will be described below with reference to the drawings.
FIG. 2 is a configuration diagram showing a main part of the brake device according to the embodiment, in which 1 is a master cylinder. The master cylinder 1 is configured to generate hydraulic pressure when the driver operates a brake pedal (not shown).
[0014]
The master cylinder 1 is connected to a wheel cylinder 3 via a brake circuit 2. In the middle of the brake circuit 2, a pressure increasing state in which the upstream (master cylinder 1 side) and the downstream (wheel cylinder 3 side) of the brake circuit 2 communicate with each other and the brake fluid in the wheel cylinder 3 is released to the drain circuit 4. A switching valve 5 is provided that can be switched between a reduced pressure state and a holding state in which the brake circuit 2 is shut off and the brake fluid pressure of the wheel cylinder 3 is maintained. Therefore, the hydraulic pressure of the wheel cylinder 2 can be arbitrarily controlled based on the switching of the switching valve 5.
[0015]
The drain circuit 4 is provided with a reservoir 6 capable of storing brake fluid. A reflux circuit 8 that connects the reservoir 6 and a position upstream of the switching valve 5 of the brake circuit 2 is provided. In the reflux circuit 8, the brake fluid stored in the reservoir 6 is supplied to the brake circuit 2. A pump 7 for refluxing is provided.
[0016]
The configuration in the range surrounded by the one-dot chain line in FIG. 2 described above is combined into one as the brake unit 11. 2 illustrates the configuration of one wheel, the overall configuration is as shown in FIG. 3, and the brake unit 11 includes four wheel cylinders 3 (FIG. 3) of four wheels FR, FL, RR, RL. The brake fluid pressure is not shown in FIG. Incidentally, the vehicle to which this embodiment is applied is a front wheel drive or a four wheel drive based on a front wheel drive vehicle.
[0017]
The operation of the switching valve 5 and the pump 7 of the brake unit 11 is controlled by a control unit 12. The control unit 12 is provided with wheel speed sensors 13, 13, 13, 13 that detect the rotational speeds of the wheels FR, FL, RR, RL as input means.
[0018]
Next, the brake control of this embodiment will be described.
The brake control of the present embodiment includes so-called ABS control that controls the brake fluid pressure for each wheel to prevent wheel lock during braking, and the brake fluid pressure of the rear wheels RL and RR during braking is not excessive. The braking force distribution control for controlling the brake fluid pressure of the rear wheels is executed. FIGS. 4 and 5 show the overall flow.
[0019]
This brake control is performed in a cycle of 10 msec. First, in step S1, the sensor frequency is obtained from the sensor pulse number ND and the cycle TD of each wheel speed sensor 13 generated around 10 msec, and the raw wheel speed Vwin is calculated. To do. In the subsequent step S2, the control wheel speed Vw is calculated by filtering the noise included in the raw wheel speed Vwin and the fluctuation due to the rotor eccentricity.
In step S3, a filtering wheel speed Vf for calculating a pseudo vehicle body speed VI in which the acceleration / deceleration is limited to the change in the control wheel speed Vw is created. The acceleration / deceleration limit means that the wheel speed change rate does not change more than the actual vehicle speed change due to slipping of the wheel during acceleration or deceleration. A value is provided.
In step S4, a control wheel acceleration ΔVw30 (that is, an average acceleration of the control wheel speed Vw for 30 msec) is calculated from the control wheel speed Vw30 30 msec before and the current control wheel speed Vw.
In step S5, the larger value of the control wheel speeds VwFL and VwFR for the front wheels FL and FR is selected to form the select high wheel speed Vif.
In step S6, the depressurization threshold (corresponding to the first boost suppression threshold in the claims) λB and the boost suppression threshold (corresponding to the second boost suppression threshold in the claims) λA for braking force distribution control are expressed by the following equations. Calculate based on.
λA = CVw
λB = AVif + B
A, B, and C are arbitrary coefficients and are set so that λA> λB. Incidentally, as the coefficient C, for example, a value slightly smaller than 1 of about 0.99 is used.
[0020]
In step S7, an ABS control process is executed. The part that performs the ABS control processing corresponds to the ABS control unit in the claims, and the contents of the control are well known, and will be described in a very simple manner with reference to FIG. 6. In step S61, the decompression threshold λ1 for ABS control is described. In step S62, it is determined whether or not the control wheel speed Vw is smaller than the depressurization threshold λ1. If the depressurization threshold λ1 is smaller than the depressurization threshold λ1, the process proceeds to step S63 and the control wheel acceleration ΔVw30 is determined. It is determined whether or not it is smaller than a set value C (C ≦ 0). If ΔVw30 ≦ C, it is determined that the wheel tends to be locked, and the process proceeds to step S65 where pressure reduction determination is performed. In the case of ΔVw30> C, it is determined that the wheel tends to return to the pseudo vehicle body speed VI, and the process proceeds to step S66 to make a holding determination.
If NO is determined in step S62 (when Vw> λ1), the process proceeds to step S64, and whether or not the control wheel acceleration ΔVw30 is less than the set value D (D> 0). If ΔVw30> D, it is determined that the wheel speed has been recovered, and the process proceeds to step S67 to determine the pressure increase. On the other hand, if ΔVw30 ≦ D, the process proceeds to step S66 and the holding determination is performed.
[0021]
Based on the above-described pressure reduction / holding / pressure increase determination, an output process for the solenoid that operates the switching valve 5 is performed in step S10 (FIG. 4) described later, whereby the wheel speed is kept within a predetermined range with respect to the pseudo vehicle body speed VI. This prevents the wheel from being locked during braking. When the ABS control is executed, the ABS flag AS is set to 1 when the first decompression process is executed, and then the pseudo vehicle body speed VI becomes lower than a predetermined value or set in advance. If the set time is exceeded, AS is reset to zero.
[0022]
Returning to FIG. 4, in step S8, it is determined by the ABS flag AS whether or not the ABS control is in progress. If AS = 1, the process proceeds to step S9. If AS = 0, the process proceeds to step S11.
In step S9, the braking force distribution control flag ASB is cleared to 0, and the decompression flag and the decompression timer are also cleared to 0. In subsequent step S10, output processing is performed toward the solenoid of the switching valve 5 as described above. Then, the process returns to step S1.
[0023]
Next, in step S11 of FIG. 5 which proceeds when it is determined that the ABS control is not being performed in step S8, the control wheel acceleration ΔVw30 of the rear wheels RL and RR is equal to or greater than a set value D (for example, D = 0.8 g). If it is equal to or greater than the set value D, it is determined that the wheel is returning to the pseudo vehicle body speed VI, and the process proceeds to step S17 to prepare for pressure increase. Then, the vehicle status determination zone ZONE = A1 is performed, and the decompression flag and decompression timer are cleared to zero.
On the other hand, if ΔVw30 <D in step S11, the process proceeds to step S12 to determine whether or not the control wheel speed Vw for the rear wheel is less than the depressurization threshold λB. If Vw ≧ λB, step S12 is performed. Proceeding to step S13, if Vw <λB, the routine proceeds to step S16 to prepare for pressure reduction (pressurization suppression), and the vehicle state determination zone ZONE = B0 is set.
In step S13, it is determined whether or not the control wheel acceleration ΔVw30 for the rear wheels RL and RR is less than a set value −3.6 g. If ΔVw30 <−3.6 g, the wheel exhibits a locking tendency. In step S15, the reduced pressure holding (pressurization suppression) is prepared. In this case, the vehicle condition determination zone ZONE = B1 is set, and the reduced pressure flag and the reduced pressure timer are reset to zero. In the case of reaching step S13, since the pressure is reduced through steps S12 and S16 before that, it may be held.
On the other hand, if ΔVw30 ≧ −3.6 g in step S13, the process proceeds to step S14, where the vehicle condition determination zone is set so as to prepare for a slight pressure increase (pressure increase suppression), a slow pressure increase (pressure increase suppression), or a rapid pressure increase. While setting ZONE = A0, the decompression flag and decompression timer are reset to zero.
[0024]
In subsequent steps S20 to S26, the vehicle status is determined based on the vehicle status determination zone ZONE, the braking force distribution control flag ASB, the pressure reduction flag, the pressure reduction timer, and the like, and steps S28 and S29 are performed based on the determination result. , S32, S33, S34, and S37, a solenoid driving process for operating the switching valve 5 is executed.
Here, the vehicle condition determination zone ZONE will be described. This zone determination is performed based on the control wheel speed VwRR (RL) of the rear wheel and the control wheel acceleration ΔVw30. In this embodiment, FIG. In the state where the braking force distribution control is executed, four types of zones A0, A1, B0, and B1 are selected. In this figure, zones indicated by L1 and L2 are zones selected during ABS control.
[0025]
In step S20, it is determined whether or not ZONE = B1orA1, and in either case, the process proceeds to step S21, and in the case of ZONE = A1, the process proceeds to step S28 to perform a rapid pressure increasing process. Here, the rapid pressure increasing process is a process for setting the switching valve 5 connected to the wheel cylinders 3 of the rear wheels RL and RR to a pressure increasing state shown in FIG. 2, and can be rapidly increased as necessary. Meaning of processing.
On the other hand, if it is determined in step S21 that ZONE.noteq.A1, the process proceeds to step S29, and holding processing, that is, processing for setting the switching valve 5 connected to the wheel cylinder 3 of the rear wheels RL and RR to the holding state is performed. .
If NO is determined in step S20, that is, if ZONE = A0 or B0, the process proceeds to step S22 to determine whether ZONE = B0. If ZONE = B0, the process proceeds to step S23.
In step S23, it is determined whether or not the decompression flag = 1. If the decompression flag = 1, the process proceeds to step S21. If the decompression flag ≠ 1, the process proceeds to step S24. In step S24, it is determined whether or not the count of the decompression timer has exceeded 3 msec. If it exceeds 3 msec, the process proceeds to step S27, the decompression flag is set to 1, and then the process proceeds to step S21. On the other hand, if the count of the depressurization timer is 3 msec or less, the process proceeds to step S30, the braking force distribution control flag ASB is set to 1, and after the depressurization timer is incremented in step S31, the process proceeds to step S32. (Pressure suppression is suppressed), that is, the switching valve 5 connected to the wheel cylinders 3 of the rear wheels RL and RR is brought into a reduced pressure state. Incidentally, the depressurization timer counts the elapsed time since the switching valve 5 is in the depressurized state, and the depressurization flag is set to 1 when this elapsed time exceeds 3 msec.
[0026]
If NO is determined in step S22, that is, if the vehicle condition determination zone ZONE = A0, the process proceeds to step S25 to determine whether or not the braking force distribution control flag ASB = 1, and ASB ≠ 1 ( In the case of ASB = 0), the process proceeds to step S35, and the same sudden pressure increase process as in step S28, that is, the process of setting the switching valve 5 connected to the wheel cylinder 3 of the rear wheels RL and RR to the pressure increasing state, If ASB = 1, the process proceeds to step S26.
[0027]
In step S26, it is determined whether or not the control wheel speed Vw for the rear wheel is larger than the pressure increase suppression threshold λA. If Vw ≦ λA, the process proceeds to step S33 to perform a slight pressure increase process (pressure increase suppression). , Vw> λA, the process proceeds to step S34 to perform a slow pressure increase process (pressure increase suppression). Here, both the slight pressure increase and the slight pressure increase are performed slightly or gently by giving a predetermined limit to the opening time of the switching valve 5 connected to the wheel cylinder 3 of the rear wheels RL and RR. For example, in the case of a slight pressure increase, the duty ratio when the switching valve 5 is opened is controlled to 5%, and in the case of a slow pressure increase, the duty ratio is controlled to 20% so as to increase compared to the time when the pressure increases slightly. Increase pressure factor.
[0028]
Further, in step S35, it is determined whether or not the number of times of pressure increase due to slow pressure increase has reached a predetermined number N (this N is a number of about 6 to 10, for example, 9 times in the present embodiment). If the predetermined number N has been reached, the process proceeds to step S36, where the braking force distribution control flag ASB is reset to 0 to stop the braking force distribution control.
[0029]
In the braking force distribution control described above, in short, the process proceeds to step S28 when the vehicle condition determination zone ZONE = A1, and the process proceeds to step S29 when ZONE = B1, or ZONE = B0 and hydraulic pressure. This is the case when flag = 1. Further, the process proceeds to step S32 when ZONE = B0, the pressure reduction flag = 0, and the pressure reduction timer ≦ 3 msec. Further, the process proceeds to steps S33, S34, and S37 to increase the pressure when ZONE = A0. If ASB = 1 and Vw> λA, the pressure is slightly increased in step S33, and ASB = 1 and Vw ≦ λA. If so, a slow pressure increase is performed in step S34, and if ASB ≠ 1, a rapid pressure increase is performed in step S37. Then, when the slow pressure increase is performed N times, it is determined that the pressure increase is insufficient, and the slow pressure increase (braking force distribution control) is canceled to return to the sudden pressure increase state.
[0030]
Next, the operation of the present embodiment will be described.
FIG. 8 shows an example of operation during a braking operation. When the braking operation is performed, the pressure of the wheel cylinder 3 (wheel cylinder pressure W / C) increases, and the wheel speeds VwFR and VwRR decrease. In the case of the example shown in this figure, at the initial stage of braking, in steps S11 to S13, all are determined to be NO, and it is determined that ZONE = A0 (rapid pressure increase). Therefore, the wheel cylinder pressure W / C also increases at the rear wheel at the same increase rate as the front wheel. And if the wheel cylinder pressure W / C of the front wheel and the rear wheel increases in the same way, the wheel load on the rear wheel is smaller, and in the case of a front wheel drive vehicle, Since the driving force is not input, the rate of decrease in the wheel speed VwRR of the rear wheel is increased, and accordingly, YES is determined in step S13 to determine ZONE = B1, and the holding process (pressure increase suppression) is performed on the rear wheel side. Thus, the increase in the wheel cylinder pressure W / C is suppressed.
[0031]
Thereafter, if the wheel speed VwRR of the rear wheel continues to decrease and falls below the pressure reduction threshold λB, it is determined that ZONE = B0. In the range where ZONE = B0 is determined, the pressure reduction process (pressure increase suppression) is initially performed based on the flow of steps S22 → S23 → S24 → S30 → S31 → S32. At this time, the braking force distribution flag ASB = 1 is set. Thereafter, the holding process is performed according to the flow of steps S24 → S27 → S21 → S29 and the flow of S23 → S21 → S29. As a result of the above decompression process and holding process, the wheel cylinder pressure W / C is controlled to a lower pressure at the rear wheels than at the front wheels, whereby the wheel speed VwRR of the rear wheels returns to a value higher than the decompression threshold λB. .
[0032]
After this return, it is determined that ZONE = A0, and during that time, a slight pressure increase process (pressurization suppression) is performed.
When the wheel speed VwRR of the rear wheel gradually decreases and falls below the pressure reduction threshold value λB by this slight pressure increase processing, it is determined again that ZONE = B0, and pressure reduction (pressure increase suppression) is executed. The speed VwRR returns to a value higher than the pressure reduction threshold λB.
In the example of FIG. 8, the driver subsequently increases the brake pedal, and as a result, the ABS control is executed.
[0033]
Next, when the braking force distribution control described above is executed, for example, the road surface μ changes from a low μ road to a high μ road (this is referred to as a μ jump), or a wheel load is applied to the turning inner wheel. The operation when the running state changes from a state in which the rear wheel is easily locked to a state in which it is difficult to lock suddenly so that the wheel load suddenly increases from a state where the vehicle does not travel straight will be described.
[0034]
In FIG. 9, t0 indicates the above-described traveling state change point, that is, in this example, this traveling state change occurs when the slight pressure increasing process is executed by the braking force distribution control described above. .
This slight pressure increase process is executed when the vehicle state is ZONE = A0, that is, is controlled based on the flow of steps S20 → S22 → S25 → S26 → S33. In such a state, when the above-described change in the running state occurs, the braking force is insufficient on the rear wheel, and the wheel speed of the rear wheel approaches the vehicle body speed. That is, as shown in the figure, when the above-described change in running state occurs at time t0 and the braking force is insufficient, the wheel speed VwRR of the rear wheels approaches the vehicle body speed Vcar and becomes higher than the pressure increase suppression threshold λA. When such a change occurs, the process proceeds from step S25 to step S34 in the flowchart, and the slow pressure increasing process is executed. Therefore, the wheel cylinder pressure W / C pressure increase rate is higher than that when the pressure is increased by the slight pressure increase process, the insufficient braking force is eliminated, and the wheel speed VwRR of the rear wheels decreases. In the figure, the two-dotted line indicates the wheel speed VwRR of the rear wheel when the slight pressure increase is maintained. In this case, the vehicle speed does not decrease from the vicinity of the vehicle body speed Vcar, and the braking force is insufficient. I can see that
Then, when the wheel speed Vw decreases again below the pressure reduction threshold λA, the process proceeds to step S26 → S33 in the flowchart, and returns to the slight pressure increase.
[0035]
Thus, in the present embodiment, during the braking force distribution control, as shown in FIG. 9, when the running state changes at time t0 and the braking force is insufficient, the pressure is increased from a slight pressure increase to a slow pressure increase. As a result, the pressure increase rate can be increased, the delay time of the deceleration acceleration rise time can be shortened, and the control quality can be improved.
Incidentally, when the above-described change in running state does not occur, as shown in FIG. 8, the wheel speed VwRR of the rear wheels does not increase to the pressure increase suppression pressure reduction threshold λA by the braking force by the slight pressure increase control. It is controlled in the vicinity of λB, and the highest braking force can be obtained in the vicinity of the depressurization threshold λB.
[0036]
Further, in the example shown in FIG. 9, an example is shown in which a sufficient braking force is obtained by the slow pressure increase and the wheel speed VwRR of the rear wheel is decreased, but the slight pressure increase is changed to the slow pressure increase, If the wheel speed VwRR does not decrease sufficiently even after repeating this slow pressure increase, the process proceeds to steps S34, S35, and S36, and the braking force distribution control flag ASB is reset to 0. As a result, the switching valve 5 increases rapidly. The brake fluid pressure of the same pressure as that of the front wheels is immediately supplied, so that the shortage of braking force can be resolved instantaneously.
[0037]
As described above, in this embodiment, the mechanical proportioning valve that prevents the rear wheel braking force from being increased and locked during braking is eliminated, and the function of this proportioning valve is reduced to ABS. In a cost-effective device obtained by executing braking force distribution control by a brake control device that executes control, conventionally, in addition to the pressure reduction threshold λB for determining whether or not to perform braking force distribution control, In addition, when the pressure increase suppression threshold λA higher than the pressure decrease threshold λB is set and the slight pressure increase control is executed in the braking force distribution control, the necessity for suppressing the pressure increase in the rear wheels suddenly decreases. This makes it possible to detect when the running state changes and the braking force is insufficient. When this is detected, first, the pressure is switched from slight pressure increase to slow pressure increase. When braking force is insufficient even when pressure is increased, it is configured to increase pressure suddenly, so it is possible to increase or decrease pressure so that the driver does not feel uncomfortable during braking force distribution control. When the braking force distribution control is executed, the road surface changes from a low μ road to a high μ road, or changes from a turning state to a straight traveling state, and the wheel load of the rear wheel on the turning inner wheel side suddenly increases. Even if a change in the running state occurs, it is possible to shorten the time for the rising delay of the decompression acceleration due to insufficient braking force, and the effect of improving the control quality can be obtained.
[0038]
As mentioned above, although embodiment was described with drawing, this invention is not limited to this embodiment.
For example, FIG. 2 shows a configuration in which the wheel cylinder 3 is depressurized / held / increased by a single switching valve 5. However, the switching valve 5 can be replaced with a normally open two-position switching mechanism that can open and close the brake circuit 2. An inflow valve and a normally closed two-position switching outflow valve capable of opening and closing the drain circuit 4 may be used.
In the embodiment, a front wheel drive vehicle or a front wheel drive vehicle-based four-wheel drive vehicle has been described as an example, but the present invention can also be applied to a rear wheel drive vehicle or a rear wheel drive vehicle-based four-wheel drive vehicle.
Further, in the present embodiment, an example in which two values of the pressure decrease threshold λB and the pressure increase suppression threshold λA are provided as the pressure increase suppression threshold of the claims has been described, but further, a value between λA and λB, It is also possible to set another pressure increase suppression threshold value with a larger value, and to execute different types of slowly increasing pressures in which the increase amount is set larger as the rotational speed of the rear wheel is larger.
[0039]
【The invention's effect】
As described above, claims 1 to 4 In the described invention, the braking force distribution control means executes the braking force distribution control when the first pressure increase suppression threshold and the second pressure increase suppression threshold are set and the rotational speed of the rear wheel falls below the first pressure increase suppression threshold. The boost suppression state is started when the rotation speed of the rear wheel is between the first boost suppression threshold and the second boost suppression threshold and between the second boost suppression threshold and the reference value. Since the switching is configured to switch, when the braking force distribution control is executed, the rotational speed of the rear wheel once decreased is restored and is higher than the first pressure increase suppression threshold, but is still lower than the second pressure increase suppression threshold and the braking force is sufficient. And when the braking force tends to be insufficient due to the return to a value higher than the second pressure increase suppression threshold, the pressure increase suppression state can be switched. In order not to give Even if it is performed, it is possible to prevent the braking force from being insufficient and to improve the control quality by finely determining whether the braking force is excessive or insufficient and switching the pressure increase suppression state accordingly. There is an effect. Also If the rotation speed of the rear wheel is between the first pressure increase suppression threshold and the second pressure increase suppression threshold, a slight pressure increase process is performed, and if it is between the second pressure increase suppression threshold and the reference value, the pressure increases slowly. Since it comprised so that a pressure process might be performed, there exists an effect that the above-mentioned control quality can be improved further. Claim 2, 3 The described invention is configured to perform the pressure increasing process for increasing the pressure with a larger pressure increasing amount when the rotational speed of the rear wheel does not decrease as much as necessary even when the slow pressure increasing process is performed for a predetermined time. A large braking force can be obtained, the shortage of the braking force can be minimized, and the effect of further improving the control quality can be obtained. Claim 4 The described invention is configured to execute the braking force distribution control based on the rotational acceleration of the rear wheels in addition to the difference between the rotational speeds of the front and rear wheels, zoning is performed according to the vehicle state, and the absolute value of the rotational acceleration is In a first zone within a predetermined range including 0 and the rotational speed of the rear wheel being larger than the first pressure increase suppression threshold, the vehicle according to claim 1 or 2, depending on the running state. 3 Since it is configured to switch the described pressure increase, it is possible to perform fine control and to further improve the control quality.
[Brief description of the drawings]
FIG. 1 is a diagram corresponding to a claim showing a brake control device of the present invention.
FIG. 2 is a hydraulic circuit diagram showing a main part of the embodiment.
FIG. 3 is an overall view of the embodiment.
FIG. 4 is a flowchart showing a brake control flow of the embodiment.
FIG. 5 is a flowchart showing a brake control flow of the embodiment.
FIG. 6 is a flowchart showing ABS control in the embodiment.
FIG. 7 is a zone characteristic diagram for vehicle status determination in the embodiment.
FIG. 8 is a time chart showing an operation at the time of execution of the braking force distribution control according to the embodiment.
FIG. 9 is a time chart showing the operation when the running state changes during execution of the braking force distribution control.
[Explanation of symbols]
a Brake unit
b Wheel cylinder
c Wheel speed sensor
d Braking force distribution control means
1 Master cylinder
2 Brake circuit
3 Wheel cylinder
4 Drain circuit
5 Switching valve
6 Reservoir
7 Pump
8 Reflux circuit
11 Brake unit
12 Control unit
13 Wheel speed sensor

Claims (4)

A brake unit configured to be capable of independently suppressing the brake fluid pressure of a wheel cylinder that brakes each wheel of the vehicle;
A wheel speed sensor for detecting the rotational speed of each wheel;
Based on the difference between the rotational speed of the front wheels and the rotational speed of the rear wheels, the brake force distribution control for operating the brake unit so as to suppress the increase in the brake fluid pressure of the rear wheels as necessary can be executed. Braking force distribution control means;
In a brake control device comprising:
The braking force distribution control means is set between a first boost suppression threshold that is lower than a reference value formed based on the rotational speed of the front wheels, and between the first boost suppression threshold and the reference value. When the second pressure increase suppression threshold is set and the rear wheel rotational speed falls below the first pressure increase suppression threshold, execution of the braking force distribution control is started, and the rear wheel rotational speed is equal to the first pressure increase suppression threshold. 2 is configured to switch the boost suppression state between the case where it is between the two boost suppression thresholds and the case between the second boost suppression threshold and the reference value ,
The braking force distribution control means performs a slight pressure increase process for slightly increasing the brake fluid pressure of the rear wheel when the rotation speed of the rear wheel is between the first pressure increase suppression threshold and the second pressure increase suppression threshold. The brake control is characterized in that when it is between the second pressure increase suppression threshold and the reference value, a slow pressure increase process is performed to increase the pressure by a larger pressure increase amount than in the case of the slight pressure increase process. apparatus. When the braking force distribution control means is in a state where the rotational speed of the rear wheels does not decrease as much as necessary even after the slow pressure increasing process is performed for a predetermined time, the pressure increasing process for increasing the pressure with a larger pressure increasing amount is performed. The brake control device according to claim 1 , wherein the brake control device is configured. The brake control device according to claim 2 , wherein the pressure increasing process after the slow pressure increasing process in the braking force distribution control means is to end the braking force distribution control. The braking force distribution control means executes the braking force distribution control based on the rotational acceleration of the rear wheels in addition to the rotational speed difference between the front and rear wheels, and the absolute value of the rotational acceleration is within a predetermined range including zero. In the first zone in which the rotation speed of the rear wheel is larger than the first pressure increase suppression threshold, switching between the slow pressure increase process, the slight pressure increase process, and the pressure increase process is performed according to the conditions, and the rotation speed of the rear wheel is the first speed. In the second zone, which is smaller than the pressure increase suppression threshold, switching between holding processing and decompression processing is performed according to conditions, and in the third zone where the rotational acceleration is lower than the first zone and the second zone, holding processing is performed, and the rotational acceleration is at high fourth zone than the first zone and second zone is configured to perform rapid increase processing, and is applied to switch according to one 3 or claims 1 in the pressure boosting switching in the first zone Claims 1, characterized in that are to 3 brake control apparatus according to any one.

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