DE4214181C2 - Method for controlling brake lining wear in the sense of compensating for differences in brake lining wear in a pressure medium-operated motor vehicle brake system - Google Patents

Description

The invention relates to a method for brake pad wear regulation in the sense of a compensation of brake pad wear differences in a pressure-operated motor vehicle brake system.

From a control loop to harmonize brake pad wear disclosing DE 33 13 078 C2 is according to an alternative a method for brake lining wear control in the sense of a Compensation for brake pad wear differences in one pressure medium-operated motor vehicle brake system derivable, wherein the brake system has a wear sensor to record each Wear of one brake pad on only one wheel at a time One service brake valve and downstream solenoid valves per axis as well as a control unit to which the signals from the wear sensors are supplied and the signals for control of the solenoid valves generated and with different wear the brake pads modified accordingly.

 Because this brake system has a brake pad wear sensor at each has only one wheel per axle, it offers the advantage of one Inexpensive solution, but has the disadvantage that the brake pad wear not taken into account on the non-sensed bike, resulting in critical driving conditions and / or poor control results can lead.

Proceeding from this, the invention is based on the object improved process for brake pad wear control at only specify a sensed wheel per axle of the motor vehicle.  

This object is achieved with the features of claim 1.

Advantageous refinements and developments of the invention according to the method are characterized by the features of the subclaims featured. While in particular with the characteristics of the An Proverb 2 the brake pad wear actual values to compensate for the Brake pad wear differences between the axles, i.e. the The front and rear axles of the vehicle are used, it is also possible according to the features of claim 3 Brake pad wear actual value to compensate for the brake pad ver wear difference between both wheels of an axle tighten because of the immediately recorded brake lining wear value a wheel is known.

An embodiment of the invention is shown in the drawing and is described in more detail below. It shows

Fig. 1 is a block diagram of a pressure-operated brake system and

Fig. 2 is a flow chart of the method according to the invention.

The motor vehicle brake system 10 shown schematically in FIG. 1 comprises a service brake valve 11 , which supplies the pressure medium from pressure reservoirs 12 a, 12 b via separate lines to the area of the front axle VA and the area of the rear axle HA; In the brake pressure line to the rear axle, an ALB controller 13 for automatic load-dependent braking force control is also inserted. The respective wheel brake cylinders are designated 14 a, 14 b for the front axle and 15 a, 15 b for the rear axle and represent actuators which shift brake pads indicated schematically with 16 a to 17 b in such a way that frictional engagement with the respective wheel brake drum result in deceleration effects on the wheels.

According to the invention, only one brake pad of one wheel of an axle is assigned a wear sensor, for example the brake pad 16 a of the right wheel of the front axle VA of the wear sensor 18 a and the brake pad 17 a of the right wheel of the rear axle HA of the wear sensor 19 a. The wear sensors 18 a, 19 a can determine the respective remaining coating thickness in a known, known manner. The outputs of the wear sensors 18 a, 19 a operate via signal lines 18 , 19 to control electronics 20 arranged centrally in the exemplary embodiment shown. The control electronics 20 give corresponding signals to solenoid valves 21 a, 21 b and 22 a, 22 b connected to the brake pressure lines for each wheel, by means of which the brake pressures on the wheel brakes are controlled and which the valves for implementing ABS (anti-lock braking system) - Functions can be. Furthermore, according to the exemplary embodiment, each wheel is also assigned a speed sensor 23 a, 23 b and 24 a, 24 b and each wheel brake cylinder 14 a to 15 b a brake pressure sensor 25 a, 25 b and 26 a, 26 b, the signals of which, like that Si signals of the service brake valve and the ALB controller via signal lines are also fed to the central control electronics 20 .

Basically, the procedure shown below in addition to the sensed brake pad wear on a wheel regulating axis also the brake pad wear on the non sensier th wheel considered without an additional (expensive) sensor to use.

For this purpose, physi sizes - for example the wheel speeds, the difference between the two wheel speeds, the wheel brake pressures and / or the wheel brake temperatures - a correction factor K is calculated, by the duration and size of these physical quantities - possibly also their derivatives - for both wheels of the concerned Axis added up in the electronic control unit and the  resulting sums for the sensed and the non-sensed wheel be compared and evaluated. The sensed brake pad ver wear is multiplied by the correction factor K if it is greater than 1 - the assumed brake pad wear on the non-sensed wheel is larger than that on the sensed wheel detected brake pad wear - and the higher-level control to harmonize brake pad wear and, if necessary, one Warning device supplied as actual value.

For the application of an electropneumatic brake EPB, in which the wheel speeds and the wheel brake pressures are recorded, the following procedure follows for each axle for brake pad wear control, Fig. 2 in conjunction with Fig. 1, in which mean:
S_D: non-volatile stored sum of all detected speed differences (or a corresponding standardized size) between the sensed and the non-sensed wheel;
S_T: non-volatile sum of all the integrals of the wheel brake pressures recorded over time;
S_A: non-volatile sum of all recorded wheel decelerations (dn / dt);
D: maximum speed difference (or a corresponding normalized variable) between the sensed and the unsensated wheel during the current braking (signed);
T: integral of the wheel brake pressure over time for the current braking;
A: wheel deceleration during the current braking;
X: brake pad wear;
Indices:
A for axis
S for sensed bike
N for not sensed bike.

Only in the case of new brake pads of the vehicle are the sums SD, ST and SA stored in a memory of the control electronics 20 possibly non-volatile in an initialization step 1 to zero. Otherwise - initiated by decision stage 2 with current braking - during braking with a possible brake pad wear control with the last transmitted brake pad wear actual value according to step 3 according to method step 4, the speeds of both wheels in a sub-step 4.1 and in a sub-step 4.3 the starting and End wheel speed based on the signals from the speed sensors 23 a, 23 b and 24 a, 24 b and in a sub-step 4.2 based on the signals from the brake pressure sensors 25 a, 25 b and 26 a, 26 b, the wheel brake pressures over the time of braking detected. Then, in a process step 5, at the end of braking, the maximum speed difference D, the integral of the wheel brake pressure over the time T _{S of} the sensed wheel and T _{N of} the non-sensed wheel, and the wheel deceleration A _{S of} the sensed wheel and A _{N of} the non-sensed wheel calculated and added in a method step 6 according to the sub-steps 6.1 to 6.5 to the assigned last stored value. From these new values, then in a step 7, a factor K = f (SD, ST _N, ST _S, SA _N, SA _S) is calculated in the braking condition in the electronic control unit 20 which then greater than "1", when the brake lining wear on the non-sensed wheel _{N is} greater than the brake pad wear on the sensed wheel _S ; With the factor K, a ratio representing the energy balance between the brake pad wear of the non-sensed wheel and the brake pad wear of the sensed wheel is derived on the basis of the physical state variables. Is discriminating circuit in the Ent 7.1 then found that K is greater than "1", in a step 8, a related to the axis of the brake lining wear X _A by multiplying the sensed brake lining wear X _S by the factor K is calculated, wherein X _A is greater X _S is.

If, on the other hand, it is determined in decision stage 7.1 that the factor is not greater than "1", the factor K = 1 is set in step 7.2 and XA = X _{S is} calculated in method step 8 , that is to say the sensed brake lining wear as brake lining wear related to the axis maintained. In procedural step 9 , X _A is then output to the brake pad wear control in the control electronics 20 , which uses this value as the actual brake pad wear value for the subsequent braking.

The procedure described above is carried out both on the front axle and on the rear axle, so that an X _AV (front axle) and X _AH (rear axle) is calculated with each braking.

For example, during the following braking, the brake pressure setpoint specified by the service brake valve 11 to the control electronics 20 is 4 bar and is the brake pressure ratio P front axle: P rear axle = P which is output by the ALB controller 13 to the control electronics, for example when the vehicle is empty so P-Before the axis = 4 bar and P-rear axle = 2 bar, they will contribute to last determined current values X _AV = X _AH these brake pressures of the control electronics via the solenoid valves 21 a, 21 b and 22 a, 22 b corresponding to modulated. If, on the other hand, X _AV greater than X _{AH has been} determined last, the control electronics will take into account this fact and, if the braking is detected as uncritical, modify the brake pressure accordingly, e.g. P front axle = 3.7 bar and P rear axle = 2.3 bar given. During this following (= current) braking, the process sequence described is again carried out, the factor K calculated in the previous braking and stored non-volatilely being overwritten by the factor K calculated in this current braking solution, so that an ongoing update therefore takes place. The factor K is reset to "1" only when the brake pads are renewed.

Due to the described Ver running with each braking driving process is ensured - although only one wheel per Axle is sensed for brake pad wear - that brake pad bearing wear differences between the axles of the vehicle be harmoniously balanced.

Alternatively, however, it can also be provided that X _AV and X _AH not at every braking, but at certain time intervals, e.g. B. after every vehicle start.

In addition, a warning device 27 can be activated by the control electronics when the calculated factor K leaves a stored predetermined value range, since a defective wheel brake is then recognized. The warning device can also be activated when the actual brake pad wear value X _{A has reached} a predetermined maximum value.

From the process sequence described it can also be seen that, depending on the desired informative value of the factor K in process steps 4 and 6, not all sub-steps 4.1 to 4.3 and 6.1 to 6.5 have to be carried out, but also only sub-steps 4.1 / 6.1 or 4.2 / 6.2 , 6.3 or 4.3 / 6.4, 6.5 lead to a meaningful factor K, as well as an additional detection of the duration and level of the temperature by means of sensors on each wheel brake during braking.

In such brake systems, in which each wheel brake cylinder, a solenoid valve is associated, and hence the brake pressure can also be controlled wheel by wheel -. As illustrated in Figure 1 - it is also possible to use the COMPUTE in process step 8 th brake lining wear actual value X _A of a radweisen brake pressure correction per axis.

For example, if an X _AV = K · X _S (K greater than 1) was last calculated on the front axle, this means that the brake lining wear on the non-sensed wheel is greater than on the sensed wheel. Starting from the previously mentioned brake pressure on the In front of the axle, P-front axle = 4 bar, a brake pressure correction per wheel is now carried out in the current braking - if this was recognized as uncritical - such that the solenoid valve 21 b in the wheel brake cylinder 14 b of the stronger Ver wear-free non-sensed wheel For example, only a brake pressure of 3.9 bar and the solenoid valve 21 a in the wheel brake cylinder 14 a of the less wear-sensitive wheel, for example. An increased brake pressure of 4.1 bar is controlled. It is evidently the other way round with X _AV = X _S (K = 1) and of course the same applies to X _AH .

This correction can now the previously described brake pressure correction between the axles (front / rear axle) be superimposed on the basis of which, according to the above example, a brake pressure correction of 0.3 bar on the front axle from 4 bar to 3.7 bar and on the rear axle from 2 bar to 2.3 bar is required. Taking this requirement into account, there is then a braking pressure of (4 bar-0.3 bar-0.1 bar =) 3.6 bar on the front axle on the non-sensed wheel and a braking pressure of (4 bar-0, 3 bar + 0.1 bar =) 3.8 bar. In contrast, the brake pressure on the wheels of the rear axle is still 2.3 bar assuming K _H = 1; however, it is then additionally corrected analogously to the front axle if K _H greater than 1 is also established on the rear axle.

Claims (8)

1. Method for brake pad wear control in the sense of a compensation of brake pad wear differences in a pressure-medium-operated motor vehicle brake system ( 10 ) with
a wear sensor ( 18 a; 19 a) for detecting the respective wear of a brake pad ( 16 a; 17 a) on only one wheel per axle (VA; HA),
a service brake valve ( 11 ) and downstream solenoid valves ( 21 a; 21 b; 22 a; 22 b) and a control unit ( 20 ) to which the signals from the wear sensors ( 18 a; 19 a) are fed and which are the signals for actuating the solenoid valves (2 1 a; 21 b; 22 a; 22 b), the method comprising the following steps:

• Determination of a brake pad wear value for the non-sensed wheel by multiplying the immediately recorded brake pad wear value (X _S ) by a factor (K) calculated from physical state variables of the sensed and non-sensed wheel of the same axle during at least one braking, which represents the ratio of the energy balance between the Reflects the braking load of the non-sensed wheel and the braking load of the sensed wheel,
• · Determination of the actual brake pad wear value (X _A ) for each axle as the larger value from the directly recorded (X _S ) and the indirectly determined (K · X _S ) brake pad wear value,
• · Modification of the signals to control the solenoid valves ( 21 a; 21 b; 22 a; 22 b) by the control unit ( 20 ) with different wear of the brake pads depending on the actual brake pad wear values (X _A ) and the calculated factors (K) of the axes.

2. The method according to claim 1, characterized in that the regulation to compensate for the brake lining wear differences between the axles (VA and HA) of the motor vehicle, the actual brake lining wear values (X _AV and X _AH ) of the axes are used. 3. The method according to claim 1 or 2, characterized in that the regulation to compensate for the brake lining wear difference between two wheels of an axle (VA or HA) of the motor vehicle, the calculated factors (K _V or K _H ) are used as a basis. 4. The method according to claim 1, characterized, that the factor (K) new at certain time intervals calculates and stored non-volatile for the subsequent braking becomes. 5. The method according to claim 1, characterized, that as physical state variables for calculating the factor (K) the speed or acceleration curves and / or the Speed differences and / or the brake pressure profiles or brake pressure gradients and / or wheel brake temperature profiles or temperature gradients the sensed and not sensed wheel of the same Axis can be detected.   6. The method according to claim 4, characterized, that the factor (K) is reset to "1" after each brake pad renewal becomes. 7. The method according to claim 1, that when the calculated factor (K) leaves a predetermined range of values, a defective wheel brake is recognized and a warning device ( 27 ) is activated by the control unit ( 20 ). 8. The method according to claim 1, characterized in that a warning device ( 27 ) is activated when a maximum value is exceeded by one of the brake pad wear values from the control unit ( 20 ).