WO1999064281A1 - Devices and methods for controlling a motor vehicle brake system - Google Patents

Abstract

The invention relates to devices and methods for controlling a brake system (4), especially for motor vehicles, in order to perform a braking assistance function. The movement of a brake pedal (1) by the driver is detected by a displacement sensor (2) and transferred to the braking system (4) via a signal line (3). A control unit (5) can either modify or reduce a damping effect and/or a counterforce of the brake pedal (1) and/or increase a system reinforcement effect according to the movement of the brake pedal (1) as detected by the displacement sensor (2), in order to reduce the braking distance of the motor vehicle safely and comfortably. In particular, the driver exercises total control over the braking process, even when the braking assistance function is activated.

Description

DEVICES AND METHOD FOR CONTROLLING A BRAKE SYSTEM FOR MOTOR VEHICLES

The invention relates to a device and a method for controlling a brake system, in particular for motor vehicles, for realizing a brake assistance function.

According to the prior art, active brake boosters are known which are used to shorten the braking distance. The brake booster is controlled externally by a so-called brake assistant. The function of the brake assistant, which improves the braking ability of a car in the hands of a less experienced driver and thus shortens the braking distance, is as follows. A displacement sensor measures the speed at which a brake pedal is depressed. If the driver hesitates after the spontaneous step on the pedal and does not dare to depress the pedal until the control of an anti-lock braking system (ABS) responds, the brake assistant intervenes. From the speed at which the driver initiated the braking process, an electronic control unit calculates whether there is emergency braking and, via a solenoid valve, gives the booster, which works in the ON / OFF process, the command to deliver the full boosting force. As a result, the vehicle is increasingly braked. A release switch is integrated in the booster so that the brake assistant, once triggered, does not unintentionally brake the vehicle to a standstill. This switches off the brake assistant as soon as the driver releases the brake pedal. The above principle is described, for example, in DE 42 08 496 Cl. A disadvantage of the above solution, however, is that, for example, an unwanted rapid actuation of the brake pedal can also lead to an external triggering of the brake system. Furthermore, in the worst case it can happen that the system is kept in the externally controlled and activated state when the driver exerts a relatively small force on the brake pedal (after activation by, for example, a quick start movement of the brake pedal). This can also lead to undesired braking. If the brake assistant senses that the driver desires to release the active booster, a jerk can still occur because the brake pressure is suddenly reduced.

The object of the invention is to provide a device and a method for controlling a brake system, in particular for motor vehicles, for realizing a brake assistance function, which implement a safe and comfortable shortening of the braking distance and avoid false tripping.

The object is achieved according to the features of the independent claims. The dependent claims show advantageous developments and embodiments of the invention.

According to the invention, a brake pedal can be used, which is decoupled from the brake system in such a way that the driver input into the system, for example the actuation path of the brake pedal, is variable and dependent on further inputs, for example the speed at which the pedal is depressed, by a control unit in which the Brake system to be implemented braking deceleration can be converted.

At this point it should be noted that of course other inputs for the implementation of the driver input via the Brake pedal can be used in the desired braking deceleration. For example, this could be the vehicle speed, the vehicle load, a measured yaw moment, the current steering angle, etc.

According to the invention, for example, a damping and / or a counterforce of the brake pedal can be set accordingly via a control unit, the control unit being able to correspondingly reduce the damping and / or the counterforce of the brake pedal when the brake assistance function is activated, and the resultant brake pedal function is then determined via a displacement sensor of the brake pedal The actuation path of the brake pedal can then be used to determine the braking deceleration to be implemented by the braking system.

According to the invention it can thus be ensured in an advantageous manner that when activated

Brake assistance function the driver controls the brake system 100 percent. This is in contrast to the prior art described above, since the brake assistant there actuates the brake system in some cases independently of the actual position of the brake pedal by means of appropriate control logic. This is excluded in the invention, since the braking deceleration of the brake system is set as a function of the determined actuation path (actual position) of the brake pedal. Because the damping and / or the counterforce of the brake pedal is reduced, it can be expected that the driver continues to depress the brake pedal than when the braking assistance function is not activated, so that the braking deceleration implemented by the braking system increases. As a result, the braking distance is reduced.

According to a further embodiment, a control unit can change a system gain depending on an actuation path determined by the displacement sensor, an actuation speed and / or an actuation acceleration of the brake pedal when the brake assistance function is activated. The system gain can correspond to a ratio of the determined actuation path to a braking deceleration to be implemented by the braking system. According to this embodiment, the counterforce and / or the damping of the brake pedal does not change, but the driver input is amplified to a greater extent via the brake pedal, so that a shortened braking distance can also be achieved when the brake assistance function is activated.

The above embodiments can of course also be implemented in combination.

Exemplary embodiments of the invention are explained in more detail below with the aid of schematic drawings. Show it:

Fig. 1 is a schematic block diagram of the invention;

2 is a graphical representation of the actuation path of the brake pedal over the actuation force; 3 shows a flowchart for changing the damping and / or the counterforce of the brake pedal;

Fig. 4 is a graphical representation of the counterforce

(Input force) of the brake pedal or the output force of the brake system proportional to the braking deceleration over time, and

Fig. 5 is a flow chart regarding an increase in system gain.

1 shows a brake pedal 1 with a displacement sensor 2. The displacement sensor 2 can detect the actuation angle of the brake pedal 1 or the actuation path of the brake pedal 1. The displacement sensor 2 is connected to a brake system 4 and in particular to a control unit 5 via a corresponding signal line 3.

Depending on the signals from the displacement sensor 2 (or the angle sensor), the control unit 5 first determines whether a braking assistance function is required or not. If this is the case, the control unit 5 determines, for example, a correspondingly reduced counterforce of the pedal components of the brake pedal 1, which are not shown. These pedal components can have a static (spring) and a speed-dependent component (damping). The counterforce can be reduced, for example, by minimizing the damping. This can be done, for example, by changing the hydraulic cross section.

The control unit 5 can also leave the damping and / or the counterforce of the brake pedal 1 unchanged and increase the system gain accordingly if the Brake assistance function has been activated. Of course, influencing the counterforce and / or the damping of the brake pedal 1 and the system reinforcement can also be combined.

Depending on the signals detected by the displacement sensor 2 (or angle sensor), the control unit 5 of the brake system 4 now determines a braking deceleration to be implemented by the brake system 4. This takes place with the aid of, for example, the determined actuation path, the determined actuation speed and / or the determined actuation acceleration, although other factors can of course also be included (for example the vehicle speed, a yaw rate, a steering angle, etc.).

Depending on the determined braking deceleration or the determined braking pressure, wheel brakes 6 are now actuated via corresponding control lines 7 in order to bring about the desired deceleration (for the sake of simplicity, only one wheel brake 6 is shown). The control lines 7 can be electrical and / or hydraulic control lines for controlling the wheel brakes 6.

2 shows a graphical representation of the actuation path over the actuation force (or the input force F _e ) of the brake pedal 2. When the brake assistant is not activated, the actuation force F _el results in an actuation path of the brake pedal 1 of xl. When the brake assistant is activated, an actuation path x2 results for the same actuation force F _{el of} the brake pedal 1. A reduction in the damping and / or the counterforce of the brake pedal results in a stronger or deeper depression of the brake pedal 1 by the driver, so that the braking distance can be effectively reduced without the complete control of the Braking events or the braking process by the driver. The same naturally also applies to the embodiment according to FIGS. 4 and 5 (as will be explained in the following).

The flow chart according to FIG. 3 is intended to schematically represent a possible sequence that is carried out, for example, by the control unit 5. This sequence is started in a step 100, in which case a query is made in a step 101 as to whether the brake assist or the brake assist function is activated. If this is not the case, the system branches back between steps 100 and 101.

As has already been explained above, the activation of the brake assistance function can be initiated by the control unit 5, for example, when the depression speed of the brake pedal 1 is greater than a threshold value (however, this is only intended to represent an example of a possible activation input of the brake assistance function).

The program then branches to a step 102 in which the damping and / or the counterforce of the brake pedal 1 is reduced. This can be done, for example, by varying the hydraulic effective cross sections of the brake pedal 1 accordingly. The actuation path x of the brake pedal 1 is then detected in a step 103 and a brake deceleration corresponding to the actuation path is determined in a step 104. Then, in a step 105, this determined braking deceleration is output to the braking system and the wheel brakes 6 are then actuated in such a way that this braking deceleration is achieved. The aforementioned process ends in a step 106. The static counterforce of the brake pedal 1 (spring and / or damping effect) can thus be limited to a value that corresponds, for example, to 30 percent braking; since the normal range of action of the driver comprises 0-30% deceleration, ie the driver knows this deceleration area or area of the pedal counterforce. This causes an accelerating excess force of the foot force on the brake pedal 1 and thus a faster foot movement and a stronger or deeper depression of the brake pedal 1. The resulting pedal travel is thus a measure of the deceleration to be implemented. The value to be set for the counterforce can depend, for example, on the speed at which the foot accelerates (detected by the speed at which the brake pedal 1 accelerates). Furthermore, a static counterforce dependent on the pedal travel (spring action) can be reduced to a value that corresponds, for example, to 30 percent braking (lower force-travel characteristic curve). This then also causes an accelerating excess force of the foot force on the brake pedal 1 and thus a faster foot movement. Furthermore, the dynamic counterforce (damping) can be reduced to a possibly speed-dependent value of the initial speed, whereby when reducing the damping, care must be taken to ensure that the tendency of the brake pedal to oscillate (self-movement of the brake pedal 1) is reliably prevented. The static pedal characteristic would be maintained and only the damping force that would prevent movement would be reduced.

In all of the above solutions, the resulting pedal travel is a measure of the deceleration to be implemented. Of course, all of the above options can also be combined in any way.

At this point it should be noted that the effect of a conventional driver actuation switch can be described by sensing the pedal movement, since the pedal is not actively moved.

4 shows an increase in the system gain. The broken lines show on the one hand the input force F _e (corresponds to the counterforce) and the output force F _a . The output force F _a is a value that corresponds to the braking deceleration. If the brake assist or brake assist function is now switched on, the system gain is increased. The solid thick line shows a maximum gain. After the brake assistant is switched off, the system gain approaches the normal gain again, so that the next time the brake system is actuated, the normal gain is present again. Approaching the normal gain takes place continuously or gradually, so that the system gain is shut down as conveniently as possible.

Of course, any gradations are possible between the dashed line of F _a and the continuous thick line of F _a . Depending on, for example, the actuation path, the actuation speed and / or the actuation acceleration of the brake pedal 1, intermediate values can be selected for the system gain, so that the increased profile of the output force F _a lies between the thick solid line and the dashed line. Of course, the determination of the system gain and thus also the reinforcement line at a certain point in time during the activation of the brake assistance function and after the activation of the brake assistance function (in the phase of continuous approximation to the normal gain) can also be dependent on other factors (for example the vehicle speed, the Vehicle weight, etc.). 5 shows an example of a possible sequence that can be carried out in the control unit 5, for example. After a start in a step 200, a branch is made to a step 201 by querying whether the brake assistance function is activated or not. If this is not the case, the system branches back between steps 200 and 201. If the brake assist function is activated, the system gain is increased in a step 202. The actuation path of the brake pedal 1 is then detected in a step 203. A braking deceleration is then determined in a step 204, which corresponds to the detected actuation path, the increased system gain in step 202 being taken into account. The braking deceleration is then output to the brake system 4 in a step 205 and the sequence ends in a step 206.

When the brake assistance function is activated, the arithmetic system gain (actuation travel or pedal travel to decelerate) is greatly increased, the counterforce of the brake pedal 1 remaining unaffected. The resulting system gain can be dependent on the pedal movement (actuation path, actuation speed and / or actuation acceleration) and is determined during the application of the brake (positive pedal speed). When the brake is released, the system gain is continuously reduced down to the normal gain.

The embodiments according to FIGS. 2 and 3 as well as 4 and 5 can of course also be combined.

Furthermore, it should be noted that the modules and functions described in the invention can also be implemented individually and / or in any combination.

Claims

claims

1. Device for controlling a brake system (4), in particular for motor vehicles, for realizing a brake assistance function in which a damping and / or a counterforce of a brake pedal (1) can be set via a control unit (5), the control unit (5) When the brake assistance function is activated, the damping and / or counterforce of the brake pedal (1) is reduced and the actuation path of the brake pedal (1), which is then detected by a sensor (2) of the brake pedal (1), to determine the brake deceleration to be implemented by the brake system (4) is used.

2. Apparatus according to claim 1, characterized in that the counterforce is dependent on the acceleration speed and / or the acceleration of the driver's brake foot and is set lower if the acceleration speed and / or the acceleration is greater.

3. Apparatus according to claim 1 or 2, characterized in that the counterforce is dependent on the pedal travel and increases with increasing actuation travel.

4. The device according to at least one of claims 1 to 3, characterized in that the damping is dependent on the acceleration speed and / or the acceleration of the driver's brake foot and is set lower if the acceleration speed and / or the acceleration acceleration is greater.

. Device for controlling a brake system, in particular for motor vehicles, for realizing a brake assistance function, in which a control unit (5), when the brake assistance function is activated, system amplification depending on an actuation path, a actuation speed and / or an actuation acceleration of a brake pedal (2) detected by a sensor (2). 1) changes, the system gain corresponding to a ratio of the determined actuation path to a braking deceleration to be implemented by the braking system (4).

6. The device according to claim 5, characterized in that the system gain is increased with an increasing actuation path, an increasing actuation speed and / or an increasing actuation acceleration.

7. The device according to claim 5 or 6, characterized in that the system gain is continuously reduced with a decreasing actuation path to a normal gain.

8. Device for controlling a brake system (4), in particular for motor vehicles, for realizing a brake assistance function, a control unit (5) having an activated brake assistance function

Damping and / or a counterforce of a brake pedal (1) is reduced and the actuation path of the brake pedal (1) determined via a sensor (2) of the brake pedal (1) is used to determine the brake deceleration to be implemented by the brake system (4) and the Control unit (5) with an activated brake assistance function, a system gain depending on the detected actuation path, an actuation speed and / or an actuation acceleration of the brake pedal (1) changes, the system gain corresponding to a ratio of the detected actuation path to the braking deceleration to be implemented by the brake system (4).

9. Method for controlling a brake system (4), in particular for motor vehicles, for realizing a brake assistance function, in which a control unit (5) carries out the following steps:

Reducing a damping and / or a counterforce of a brake pedal (1) with an activated brake assistance function and

The actuation path of the brake pedal (1), which is then detected via a sensor (2) of the brake pedal (1), is used to determine the brake deceleration to be implemented by the brake system.

10. Method for actuating a brake system (4), in particular for motor vehicles, for realizing a brake assistance function, in which a control unit (5), when the brake assistance function is activated, system amplification depending on an actuation path, an actuation speed and / or detected by a sensor (2) an actuation acceleration of a brake pedal (1) changes, the system gain corresponding to a ratio of the detected actuation path to a braking deceleration to be implemented by the brake system (4).

11. Method for controlling a brake system (4), in particular for motor vehicles, for realizing a brake assistance function, in which a control unit (5) carries out the following steps: Reducing damping and / or counterforce of a brake pedal (1) when the brake assist function is activated,

The actuation path of the brake pedal (1), which is then detected via a sensor (2) of the brake pedal (1), is used to determine the brake deceleration to be implemented by the brake system (4) and to change it when one is activated

Brake assistance function, a system amplification depending on the actuation path, the actuation speed and / or the actuation acceleration of the brake pedal (1), the system amplification corresponding to a ratio of the detected actuation path to the braking deceleration to be implemented by the brake system (4).