EP1324906A1 - Method and control system for controlling an electronically regulated brake actuating system - Google Patents

Abstract

The invention relates to a method in addition to control systems for controlling an electronically regulated brake actuating system in a vehicle, comprising a depressurised pressure-medium container, and at least one pressure source which can be controlled by an electronic control unit, said pressure source being used to exert pressure on the wheel brakes of the vehicle. Pressure sensors and pressure control valves are associated with the wheel brakes of the vehicle. Said sensors and valves can be controlled in an analog manner by means of an electric variable according to the pressure differential between them and selectively connect the wheel brakes to the pressure source or pressure medium container. In order to adapt the relation between the electric variable and the pressure differential with respect to manufacture spread and the effects of ageing together with changing environmental conditions the electric variable Iein in the pressure control valve to be identified is slowly modified in the pressure maintenance phase, until a noticeable change of pressure occurs in the wheel brake associated with the pressure control valve, whereupon a correction of the relation between the electric variable and the pressure differential is carried out. Alternatively, the frequency of the control processes of the pressure control valve is taken into account.

Description

Method and control system for controlling an electronically controllable brake actuation system

The invention relates to a method for actuating an electronically controllable Bre actuation system for motor vehicles, with a pressureless pressure medium reservoir, with at least one pressure source that can be controlled by an electronic control unit, the pressure of which can be applied to the vehicle's wheel brakes, to which pressure sensors and pressure regulating valves (intake valve; exhaust valve) are assigned which can be controlled analogously by means of an electrical variable depending on the differential pressure applied to them and which connect the wheel brakes to the pressure source in a pressure build-up phase, are closed or closed in a pressure maintenance phase and connect the wheel brakes to the pressure medium reservoir in a pressure reduction phase.

Such a brake actuation system is known for example from EP 0 832 019 B1. The pressure control valves of the known brake actuation system assigned to the wheel brakes are designed as paired, electromagnetically controllable valves of the seat valve type, of which the inlet valves connected in the connection between the pressure source and the wheel brakes are designed as normally closed seat valves and fulfill a pressure limiting function in their closed switching position, while

BESTATIGUNGSKOPIE the outlet valves connected in the connection between the wheel brakes and the pressure medium reservoir are designed as normally open valves which release the connection in their open switching position and shut off in their closed switching position.

However, the publication mentioned above does not reveal any measures which make it possible to adapt the control characteristic of the pressure control valves to production variations and aging effects, as well as changing ambient conditions.

It is therefore an object of the present invention to provide methods for controlling an electronically controllable

To propose brake actuation systems of the type mentioned at the outset as well as control systems which guarantee the constant quality of the pressure control by enabling the control characteristics of the pressure control valves to be reliably adapted to disruptive influences which impair their perfect functioning.

This object is achieved according to a first method in that the electrical variable in the pressure control valve to be identified (intake valve; exhaust valve) is slowly varied in the pressure holding phase until a recognizable pressure change takes place in the wheel brake assigned to the pressure control valve, after which a correction of the dependence of the electrical Size of the differential pressure is performed.

To substantiate the idea of the invention, it is provided that the pressure control valves (inlet valve; outlet valve) are designed as closed valves in the idle state and that the variation in the electrical control variable is an increase that assumes a value which is below the value which is required for opening the pressure regulating valve (inlet valve; outlet valve).

Another alternative is that the pressure-reducing pressure control valves (exhaust valves) are designed as open valves in the idle state and that the variation in the electrical control variable is a reduction which starts from a value which is above the value which is used to hold the Pressure control valve (exhaust valve) is required when closed.

It is particularly useful if the variation of the electrical variable occurs in certain driving situations, for example when the vehicle is at a standstill, in a certain area of the vehicle speed, with a low rate of change of a wheel pressure setpoint, or with a minimum duration of the pressure maintenance phase. The variation of the electrical control variable is terminated when the difference between the target pressure and the actual pressure leaves a predetermined tolerance range, the limits of which are determined as a function of the vehicle speed.

According to a further advantageous feature of the invention, the pressure control valves are designed as electromagnetically controllable valves and the electrical variable is an electrical current to be supplied to the electromagnetic drive, or the pressure control valves are designed as piezoelectrically controllable valves and the electrical variable is an electrical voltage to be supplied to the piezo drive.

A sensible development of the inventive concept is that the pressure curve in the wheel brake assigned to the pressure control valve during the variation of the electrical Size is observed cyclically in a time window and the maximum or minimum pressure value is determined in each case, which in turn is used to determine a detection threshold for the pressure change at the outlet or input of the pressure control valve serving to build up or reduce the pressure.

In this case, in the case of a pressure control valve serving to build up pressure, a detection threshold E in window i according to the formula is preferred

E = Max (p) l window (i-1) + e fixed,

where e is a process parameter that takes into account the valve leakage and disturbances of the pressure sensor that detects the pressure profile.

When the detection threshold is exceeded by the pressure value at the output of the pressure control valve at a time tdetekt, the pressure control valve (intake valve) is opened.

In contrast, in the case of a pressure control valve serving to reduce the pressure, a detection threshold E in the window i according to the formula

E = Max (p) l window (i-1) - e fixed,

where e is a process parameter that takes into account the valve leakage and disturbances of the pressure sensor that detects the pressure profile.

When falling below the detection threshold by the pressure value at the input of the pressure control valve at a time t _de TEKT is closed on the opening of the pressure control valve (exhaust valve). In an advantageous development of the method according to the invention, at the point in time (tdetekt) that the detection threshold is exceeded or undershot by the pressure value at the outlet of the pressure regulating valve (inlet valve) used to build up the pressure or at the inlet of the pressure regulating valve (outlet valve) serving to reduce the pressure, a point in time according to formula

t-react ⁼ tdetect ~ ^~ t

calculated, where τ denotes the time offset between the reaction of the pressure control valve caused by the control and the detection of this reaction based on the pressure change.

The time offset is preferably determined as a function of a signal characterizing the viscosity of the pressure medium.

According to a further advantageous feature of the invention, the dependence of the control current I (Δp) on the differential pressure (Δp) is corrected in particular in the case of electromagnetically controllable valves according to the formula

I (Δp) " ^eU = I (Δ _P ) ^ait • (1-λ) + λ« Ireakt,

where Ireat the control ^current value corresponding to the pressure change in the wheel brake assigned to the pressure control valve at the time (t _rea kt), I (Δp) ^aI the value of the dependence of the control current I _Q (Δp) on the differential pressure (Δp) at the current operating point (Δp) before Carrying out the correction (adaptation) and I (Δp) ^now denote the value of the dependence of the control current I _c (Δp) on the differential pressure (Δp) after the (adaptation) has been carried out. The adaptation rate λ is to be selected from the interval (0, 1). In the case of piezoelectrically controllable valves, the dependence of the voltage U _D (Δp) on the differential pressure (Δp) is corrected according to the formula

U (Δp) * ^eu = U (Δp) ^aIt • (1-λ) + λ • U _reactive ,

wherein U _r ea _k t is the change in pressure in the associated pressure control valve wheel brake corresponding drive voltage at the time (t _rea kt), U (Ap) ^aI the value of the dependency of the driving voltage U (Dp) from the differential pressure (Ap) in the current operating point (Ap ) before performing the correction (adaptation) and U (Δp) ^{πeu denote} the value of the dependence of the control ^voltage U (Δp) on the differential ^pressure (Δp) after the correction (adaptation) has been carried out, the adaptation rate λ from the interval (0, 1] is to be selected.

According to a second method, the above-stated object is achieved in that the frequency of the control processes of the pressure control valve (intake valve; exhaust valve) is determined and used in accordance with a setpoint pressure curve to be controlled in the wheel brake to correct or reduce the dependency of the electrical variable on the differential pressure. This method, which is only limited to the lowering of the control characteristic, can also be used outside of pressure maintenance phases.

It is particularly useful if the number of control processes of the pressure control valve (exhaust valve) used to reduce the pressure is determined when the setpoint pressure curve is increasing or constant, and if a threshold value is exceeded, it is concluded that the pressure control valve (intake valve) serving to build up pressure is being activated too strongly or if the number of Control processes of the pressure control valve (inlet valve) which serves to build up pressure is determined, and that if a threshold value is exceeded, it is concluded that the pressure control valve (outlet valve) serving to reduce the pressure is being driven too strongly.

According to a further advantageous feature of the invention, the determined number (Na _h , N _Auf ) is compared with a maximum permitted numerical value (Nω, *, N _Auf *), which is based on the formula

Nat * = f _B • T _AU f or N _Auf = f _B • Tat is formed, whereby

f _B a maximum permissible driving frequency and _T, Indeed, the duration of the rise and fall phase designate the desired pressure curve. If the maximum permitted numerical value (Nu. *, N _Auf *) is exceeded, it is concluded that the pressure control valve (inlet valve, outlet valve) that serves to increase or decrease the pressure is too strong.

Further advantageous features of the second method according to the invention can be found in subclaims 26 to 29.

A control system according to the invention for performing the previously mentioned method is characterized in that a pressure controller is provided, to which, as input variables, a pressure setpoint with which one of the wheel brakes of the vehicle is to be applied, an actual pressure value with which one of the wheel brakes of the Vehicle is acted upon, as well as the hydraulic differential pressure value applied to the pressure control valve under consideration and the output variable of which is the desired value of the electrical variable used to control the pressure control valve, and that means for Correction (adaptation) of the dependence of the electrical variable on the differential pressure value are provided.

In addition, it is particularly advantageous if the pressure regulator consists of a linear regulator, a pilot control module and a correction module, the control deviation formed from the pressure setpoint and actual pressure value being supplied to the linear regulator, while the pilot control module is supplied with one on the pressure control valve under consideration applied signal representing hydraulic differential pressure is supplied, the pilot control module generating a pilot control value of the electrical variable used to control the pressure control valve, which corresponds to the opening point of the pressure control valve and to the output variable of the linear regulator to form the setpoint of the electrical variable used to control the pressure control valve and the correction _{module is} supplied with the actual pressure value and the differential pressure as input variables and its output variable (K ₁₇ K ₂ ) influences the behavior of the pilot control _module .

The output variable (Ki) of the correction module is preferably as a difference:

K _λ = I (Ap) ^MU - I (Δp) ^aIt or

Kj. = U (Δp) ^πeu - U (Δp) ^alt defined, where

I (Δp) ^lt or U (Δp) ^aIt the value of the dependence of the electrical control ^variable I (Δp) or U (Δp) on the differential pressure (Δp) at the current operating point (Δp) before the correction (adaptation) and I (Δp) ^πeu or U (Δp) ^{πeu denote} the value of the electrical actuation ^variable I (Δp) or U (Δp) from the differential pressure (Δp) after the correction (adaptation) has been carried out. Finally, in a control system for performing the second method according to the invention it is provided that the correction module is additionally supplied with the pressure setpoint (Psoii) as an input variable and that its output variable K ₂ = -ΔI from the comparison of the determined number of activation processes (ah, N _ÄU f) is derived with a maximum permitted numerical value (Nab *, N _Auf *), the dependency of the electrical quantity being reduced when the maximum permissible numerical value (Na _- *, N _Auf *) is exceeded.

The invention is explained in more detail in the following description using an exemplary embodiment with reference to the accompanying drawings. The drawing shows:

Fig. 1 is a simplified circuit diagram of a

Brake actuation system in which the method according to the invention can be used

Fig. 2 is a diagrammatic representation of the

Wheel brake pressure curve for determining a threshold value for an electromagnetically actuated pressure control valve that serves to build up pressure;

Fig. 3 is a diagrammatic representation of the

Wheel brake pressure curve for determining a threshold value for an electromagnetically actuated pressure control valve that serves to reduce the pressure;

4 shows the structure of a pressure regulator for carrying out the first-mentioned method according to the invention; 5 shows the structure of a pressure regulator for carrying out the second method according to the invention; and

FIG. 6 shows the function of the pilot control module shown in FIG. 4.

The electronically controllable brake actuation system shown in FIG. 1 consists of a two-circuit master brake cylinder or tandem master cylinder 2, which can be actuated by means of an actuation pedal 1, which interacts with a pedal travel simulator 3 and has two separate pressure chambers which are connected to an unpressurized pressure medium reservoir 4. Wheel brakes 7, 8, for example, which are assigned to the front axle, are connected to the first pressure chamber (primary pressure chamber) by means of a lockable first hydraulic line 5. The line 5 is shut off by means of a first isolating valve 11, while an electromagnetically actuated, preferably normally open (SO) pressure compensation valve 13 is inserted in a line section 12 connected between the wheel brakes 7, 8, which enables brake pressure control to be set individually for the wheel, if required.

The second pressure chamber of the master brake cylinder 2, to which a pressure sensor 15 can be connected, can be connected to the other pair of wheel brakes 9, 10 assigned to the rear axle via a second hydraulic line 6 which can be shut off by means of a second separating valve 14. An electromagnetically actuated, preferably normally open (SO) pressure compensation valve 19 is again inserted in a line section 16 connected between the wheel brakes 9, 10. Since the structure of the second pressure chamber of the master cylinder 2 li¬

connected hydraulic circuit identical to that of the brake circuit 11 explained in the above description, it need no longer be discussed in the text below.

As can further be seen from the drawing, a motor-pump unit 20 serving as an external pressure source is provided with a high-pressure accumulator 21, which in turn consists of a pump 23 driven by an electric motor 22 and a pressure relief valve 24 connected in parallel with the pump 23. The suction side of the pump 23 is connected to the previously mentioned pressure medium reservoir 4 via a pressure relief valve 24. The hydraulic pressure applied by the pump 23 is monitored by a pressure sensor (not shown) or determined by estimation.

A third hydraulic line 26 connects the high-pressure accumulator 21 to the input connections of two electromagnetically controllable, normally closed 2/2-way valves 17, 18, which are connected upstream of the wheel brakes 7 and 8 as inlet valves. In addition, the wheel brakes 7, 8 are each connected via an electromagnetically controllable, normally closed 2/2-way valve or outlet valve 27, 28 to a fourth hydraulic line 29, which on the other hand is connected to the unpressurized pressure medium reservoir 4. The hydraulic pressure prevailing in the wheel brakes 7, 8 is determined with the aid of one pressure sensor 30, 31 each.

An electronic control unit 32, which interacts as input signals, the output signals of an actuator pedal 1, is used to jointly control the motor-pump assembly 20 and the electromagnetic valves 11, 13, 14, 17, 18, 19, 27, 28. kenden actuation travel sensor 33 and the aforementioned pressure sensor 15 are supplied and enable driver deceleration request detection. However, other means, for example a force sensor that senses the actuating force on the actuating pedal 1, can also be used to detect the driver's deceleration request. As further input variables, the electronic control unit 32 is supplied with the output signals from the pressure sensors 30, 31 and the output signals corresponding to the speed of the vehicle from wheel sensors which are only indicated schematically, the wheel sensors assigned to the wheel brakes 7, 8 being provided with the reference numerals 34, 35.

It is generally known that the electrical quantity used to control the aforementioned inlet (17, 18) and outlet valves 27, 28, in the illustrated embodiment the electrical current, from the hydraulic differential pressure applied to the pressure control valve to be identified, which in the text below Δp is called, is dependent.

To adapt the dependency between the electrical current and the differential pressure, the so-called control characteristic of the pressure control valves to disruptive influences, such as

Production variations and aging effects, as well as changing environmental conditions, the methods according to the invention are used, the implementation of which is explained in the following text in connection with FIGS. 2-6. It must be taken into account here that the first method can only be used during the so-called pressure maintenance phase, in which all pressure control valves 17, 18, 27, 28 are closed or are closed. It is assumed that, as previously described, all pressure control valves 17, 18, 27, 28 as, 2/2-way valves which are closed when de-energized and which can be controlled analogously by means of an electromagnetic drive. Accordingly, the control characteristic of the valves, ie the dependence of the electric current to be supplied to the electromagnetic drive on the hydraulic differential pressure Δp present at the inlet (17, 18) or outlet valve (27, 28), (that in the aforementioned electronic control unit 32 is corrected or adjusted as follows:

For each pressure control valve to be identified, for example the inlet valve 17 (FIG. 1), the pressure curve p (t) in the wheel brake 7 associated with this inlet valve 17 is cyclically observed and in each case by means of the pressure sensor 30 in a time window T _w (see FIG. 2) the maximum signal value determined during this period. A method parameter e is added to the determined maximum value, which takes into account a leak occurring at valve 17 as well as malfunctions of pressure sensor 30. As a result, threshold values Ei, E ₂ , E ₃ • • • are determined in the individual time windows i (i = 0,1,2,3, ...) according to the following formula:

E = Max (p) l window (i-1) + e

It is now assumed that a certain driving situation, for example a vehicle standstill, occurs at time t ₀ (see FIG. 2) and a pressure maintenance phase (Δp = 0) is recognized. At this point in time, the electromagnetic drive of the inlet valve 17 is energized and the current I _E in slowly increased, with the pressure curve in each time window ₁ , ₂ , ₃ ,... With the previously determined threshold value Ei, E ₂ , E ₃ . .. is compared. If the threshold value E ₃ (in the time window 3) when the inlet valve 17 is actuated at the time t _de tect exceeded, a pressure change is recognized and the control characteristic for the current operating point Δp is corrected. The control current value Ireat set at the time t _rea kt = tdetect - τ is used as the correction value, the value τ indicating the expected response time of the intake valve / wheel brake system. If the temperature of the hydraulic components is recorded, the temperature dependence of the reaction time can be taken into account. The control characteristic I (Δp) is preferably corrected on the basis of the value of the control current I _react at the time t _react , preferably according to an adaptation specification of the form

I (Δ _P ) ^new = I (Δ _P ) ^aIt • (1-λ) + λ • I _r act

the adaptation rate λ is to be selected from the interval (0, 1). Small values λ lead to greater robustness against incorrect measurements, values λ close to 1 result in a faster adaptation of the stored control characteristic to the observed valve behavior

Adaptation specification denotes I (Δp) ^ait the value of the control characteristic I (Δp) at the current operating point Δp before the adaptation is carried out, while I (Δp) ^now denotes the value after the adaptation.

The method according to the invention has been described in connection with an inlet valve which serves to build up pressure and which is actuated by means of an electromagnetic drive which can be controlled by electric current. However, the procedure described can of course also be used in the case of electromagnetically actuated outlet valves which serve to reduce pressure. A corresponding, simplified Illustration is shown in Fig. 3. The method can also be applied analogously to pressure control valves which are actuated by means of a piezo drive. In this case, the variable influencing the actual behavior of the piezo valves is the voltage to be applied to the piezo drive.

The second method according to the invention consists essentially in a reduction in the control characteristic with a limit-stable control loop behavior. The described method is used to detect limit-stable states of the pressure control loop, which are caused by a control characteristic I (Δp) or U (Δp) that is set too high, the method also being able to be used outside the pressure-holding phase mentioned above. The term limit stability is understood here to mean a frequent change of control processes of the intake and exhaust valves with constant, monotonically increasing or monotonously decreasing target pressure. This behavior is associated with a wheel brake pressure oscillating around the setpoint pressure value.

The detection of the situation described and the assignment for controlling the intake and exhaust valve is based on the following basic idea:

The frequency of the exhaust valve actuation processes with increasing or constant setpoint pressure value is an indicator for an excessive actuation of the intake valve, while the frequency of the intake valve actuation processes with decreasing or constant setpoint pressure value is an indicator for an excessive actuation of the exhaust valve. To take advantage of these relationships, pressure rise and fall phases within the setpoint pressure curve are classified on the basis of its change over time, the duration of the pressure rise phase being denoted by T _up and the duration of the pressure drop phase by deed. During a pressure rise phase (T _Auf ), the number (N ^) of the activation processes of the outlet valve 27, 28 serving to reduce the pressure is determined. Similarly, during a pressure drop phase (Tab), the number (N _Auf ) of the activation processes of the inlet valve 17, 18 serving to build up pressure is determined.

At the end of the respective phase, the determined number N ^ or N _{AUf of} the control processes is compared with a maximum permitted numerical value (Nah *, N _Au -. *), For which the following equations apply:

N _Ä B * = f _B • T _up and N _up = f _B • Tab, where

f _B denotes a maximum permitted control frequency. The parameterizable control frequency f _B takes into account the fact that a certain number of overshoots or undershoots can be expected even when the pressure regulator is ideally configured.

If the determined number Nah, N _ÄU f of the actuation _{processes lies} above the maximum permitted numerical value ^ *, N _A f *, this is due to excessive actuation of the inlet valve 17, 18 or outlet valve 27, 28 serving to build up or reduce pressure returned.

In the event of a limit stability of the pressure control loop detected by the described algorithm due to excessive activation of an intake or exhaust valve, the control characteristic I (Δp) stored for the relevant valve in the electronic control unit 32 is carried out according to the following adaptation regulation:

I (Δp) ^new = I (Δp) ^aIt - Δl. The pilot control characteristic is thus reduced by a predetermined amount Δl. In this case, I (Ap) ^al referred to the value of the control characteristic of I (Ap) in the current operating point Dp before performing the adaptation, while I (Ap) ^{re-designates} the value after the adaptation.

4 to 6, finally, a pressure regulator for performing the method according to the invention is shown. The illustrated pressure regulator 40, which forms part of the aforementioned electronic control unit 32, is used as

Input variables supplied signals that the pressure setpoint Psoll with which one of the wheel brakes 7, 8 is to be applied

^Actual pressure value Pist / ^with one of the wheel brakes 7, ⁸ applied, and represent the differential pressure Δp present at the corresponding pressure control valve. The output variable of the pressure regulator 40 represents the setpoint I _so ιι or U _S oiι of the electrical current to be supplied to the electromagnetically controllable pressure control valve or the voltage to be applied to the piezoelectrically controllable pressure control valve.

The pressure regulator shown in FIGS. 4 and 6 is particularly suitable for carrying out the first method according to the invention. As can be seen in the figure, the pressure regulator 40 mentioned above is essentially formed by a linear regulator 41, a pilot control module 42 and a correction module which is provided with the reference symbol 45. A control deviation is used as the input variable of the linear controller 41

ΔPR used, the subtraction point 43 upstream of the linear controller 41 from the pressure setpoint Psoii and the actual pressure value Pι _{st is} formed, while in an addition point 44 to the output variable I _S O _II , or U _So ιι, _{L of} the linear controller 41, the output variable I _S oiι, v or U _So ιι, v des Pre-control module 42 is added. In the correction module 45, the aforementioned signals Pist and ΔP are processed to a correction variable Ki, which influences the behavior of the pilot control module 42 in the sense of the correction or adaptation described above. The correction variable K _L , as indicated by the arrow shown vertically, adapts the pre-control characteristic I _S oiι, v or U _So ιι, v a'r- stored in the pre-control module 42 to the observed valve behavior. As shown in FIG. 6 using the example of an electromagnetically controllable pressure control valve, the pilot control characteristic I _So n, v = f (Δp) is shifted “upward” by the value of the correction variable Ki in the case shown, ie to higher current values.

The pressure regulator shown in FIG. 5 is particularly suitable for carrying out the second method according to the invention. As can be seen in the figure, its structure corresponds essentially to that of the pressure regulator described in connection with FIGS. 4 and 6. In its correction module 46, however, the pressure setpoint Psoii, the actual pressure value Pι _st and the differential pressure ΔP applied to the pressure control valve to be identified are processed into a correction variable K ₂ , which, as indicated by the downward-pointing arrow, is reduced if necessary of the input tax characteristic.

Claims

claims

1. Method for controlling an electronically controllable brake actuation system for motor vehicles, with a pressure-free pressure medium reservoir (4), with at least one pressure source (20) that can be controlled by an electronic control unit (32), with the pressure of which wheel brakes (7, 8, 9, 10) Vehicle can be acted upon

Pressure sensors and pressure control valves (inlet valve 17, 18; outlet valve 27, 28) are assigned, which can be controlled analogously by means of an electrical variable as a function of the differential pressure applied to them and which the wheel brakes (7-10) in a pressure build-up phase with the pressure source (20 ) connect, are closed or are closed in a pressure maintenance phase and connect the wheel brakes (7 - 10) to the pressure medium reservoir (4) in a pressure reduction phase, characterized in that the electrical quantity in the pressure control valve to be identified (inlet valve 17, 18; outlet valve 27,28) is slowly varied in the pressure holding phase until a recognizable pressure change takes place in the wheel brake (7,8) assigned to the pressure regulating valve (inlet valve 17,18; outlet valve 27,28), after which a correction of the dependence of the electrical variable on the differential pressure takes place is carried out.

2. The method according to claim 1, characterized in that the pressure control valves (inlet valve 17,18; outlet valve 27,28) are designed as closed valves in the idle state and that the variation of the electrical control variable is an increase which starts from a value which is below the Value is that for opening the pressure control valve (Inlet valve 17, 18; outlet valve 27, 28) is required.

3. The method according to claim 1, characterized in that the pressure reduction serving pressure control valves (outlet valve 27,28) are designed as open valves in the idle state and that the variation of the electrical control variable is a reduction which starts from a value which is above the value that is for holding the pressure control valve

(Outlet valve 27, 28) is required in the closed state.

4. The method according to any one of claims 1 to 3, characterized in that the variation of the electrical variable takes place in certain driving situations.

5. The method according to any one of claims 1 to 3, characterized in that the variation of the electrical size takes place when the vehicle is stationary or in a certain range of vehicle speed.

6. The method according to any one of claims 1 to 3, characterized in that the variation of the electrical variable takes place at a low rate of change of a brake pressure setpoint.

7. The method according to any one of claims 1 to 3, characterized in that the variation of the electrical variable takes place after a minimum duration of the pressure maintenance phase.

8. The method according to any one of claims 1 to 7, characterized in that the variation of the electrical control variable is terminated when the difference between the target pressure and the actual pressure leaves a predetermined tolerance range.

9. The method according to claim 8, characterized in that the limits of the tolerance range are determined depending on the vehicle speed.

10. The method according to any one of claims 1 to 9, characterized in that the pressure control valves (17, 18; 27, 28) are designed as electromagnetically controllable valves and that the electrical variable is an electrical current to be supplied to the electromagnetic drive (I).

11. The method according to any one of claims 1 to 9, characterized in that the pressure control valves are designed as piezoelectrically controllable valves and that the electrical variable is an electrical voltage (U) to be applied to the piezo drive.

12. The method according to any one of the preceding claims 1 to 11, characterized in that the pressure profile in the wheel brake (7, 18) associated with the pressure control valve (17, 18) is observed cyclically in a time window (T _w ) during the variation of the electrical variable and in each case the maximum pressure value is determined, which in turn is used to determine a detection threshold (E) for the pressure change at the outlet of the pressure control valve (inlet valve 17, 18) which serves to build up pressure.

13. The method according to any one of the preceding claims 1 to 11, characterized in that the pressure profile in the wheel brake (7, 8) assigned to the pressure control valve (7, ₈ ) is observed cyclically in a time window (T _w ) during the variation of the electrical variable and in each case the minimum pressure value is determined which is used to determine a detection threshold (E) for the pressure change at the input of the the pressure reduction serving pressure control valve (outlet valve 27,28) is used.

14. The method according to claim 12, characterized in that a detection threshold E in the window i according to the formula

E = Max (p) l window (i-1) + e is set,

where e is a process parameter that takes into account the valve leakage and faults in the pressure sensor (30, 31) that detects the pressure profile.

15. The method according to claim 14, characterized in that when the detection threshold (E) is exceeded by the pressure value at the outlet of the pressure control valve (inlet valve 17, 18) in the time window (i), the opening of the pressure control valve (inlet valve 17, 18) is closed.

16. The method according to claim 13, characterized in that a detection threshold E in the window i according to the formula

E = Max (p) l window (i-1) - e is determined

where e is a process parameter that takes into account the valve leakage and faults in the pressure sensor (30, 31) that detects the pressure profile.

17. The method according to claim 16, characterized in that when falling below the detection threshold (E) by the pressure value at the input of the pressure control valve (outlet valve 27,28) in the time window (i) on the opening of the pressure control valve (outlet valve 27,28) is closed.

18. The method according to any one of claims 12 to 17, characterized in that at the time (tdetekt) of exceeding or falling below the detection threshold (E) by the pressure value at the outlet of the pressure control valve serving to build up pressure (inlet valve 17, 18) or at the inlet of the pressure reduction valve (exhaust valve 27, 28) serving to reduce the pressure is a point in time according to the formula

t-reactive ⁼ * -detected ^- t

is calculated, where τ denotes the time offset between the reaction of the pressure control valve caused by the control and the detection of this reaction on the basis of the pressure change.

19. The method according to claim 18, characterized in that the time offset (τ) is determined depending on a signal characterizing the viscosity of the pressure medium.

20. The method according to any one of the preceding claims 10 and 12 to 19, characterized in that the correction of the dependence of the drive current I (Δp) on the differential pressure

(Δp) according to the formula

I (Δp) ^πeu = I (Δp) ^ait • (1-λ) + λ • Ireact occurs,

where Ireakt the control current value corresponding to the pressure change in the wheel brake (7,8) assigned to the pressure control valve (intake valve 17,18; exhaust valve 27,28) at the time (t _react ), I (Δp) ^al the value of the dependency of the control current I ( Δp) from the differential pressure (Δp) at the current operating point (Δp) before carrying out the correction (adaptation) and I (Δp) ^new the value of the dependence of the control current I (Δp) on Designate the differential pressure (Δp) after the correction has been carried out (adaptation), the adaptation rate λ being chosen from the interval (0,1).

21. The method according to any one of the preceding claims 11 to 19, characterized in that the correction of the dependence of the voltage to be applied U (Δp) on the differential pressure (Δp) according to the formula

U (Δp) ^new = U (Δp) ^aI • (1-λ) + λ • U _r ea _k t occurs,

where U _r e _ak t is the control voltage value corresponding to the pressure change in the wheel brake assigned to the pressure control valve at the time (t _react ), U (Δp) ^It the value of the dependence of the control voltage U (Δp) on the differential pressure (Δp) at the current operating point (Δp ) before carrying out the correction (adaptation) and U (Δp) ^now denote the value of the dependence of the control voltage U (Δp) on the differential pressure (Δp) after the correction (adaptation) has been carried out, the adaptation rate λ from the interval (0, 1] is to be selected.

22. A method for controlling an electronically controllable brake actuation system for motor vehicles, with a pressure-free pressure medium reservoir (4), with at least one pressure source (20) that can be controlled by an electronic control unit (32), the pressure of which can be applied to the vehicle's wheel brakes (7, 8), to those

Pressure control valves (inlet valve 17, 18; outlet valve 27, 28) are assigned, which can be controlled analogously by means of an electrical variable depending on the differential pressure applied to them and which connect the wheel brakes (7, 8) to the pressure source (20) in a pressure build-up phase , are closed or closed in a pressure holding phase and connect the wheel brakes (7, 8) to the pressure medium reservoir (4) in a pressure reduction phase, characterized in that the frequency of the control processes of the pressure control valves (inlet valve 17, 18; outlet valve 27, 28) is determined and in accordance with one in the wheel brakes ( 7,8) target pressure curve to be controlled is used to correct (decrease) the dependence of the electrical variable (I, U) on the differential pressure (Δp).

23. The method according to claim 22, characterized in that the number (Nu) of the control processes of the pressure relief valve (outlet valve 27, 28) serving to reduce the pressure is determined during a pressure rise phase of the setpoint pressure profile of the duration (T _up ), and that when a threshold value is exceeded, an excessive control of the pressure control valve (inlet valve 17, 18) serving to build up pressure is closed.

24. The method according to claim 22, characterized in that during a pressure drop phase of the desired pressure curve of the duration (T ^) the number (N _Auf ) of the control processes of the pressure build-up pressure control valve (inlet valve 17, 18) is determined, and that when a threshold value is exceeded a too strong control of the pressure reduction valve serving to reduce pressure (outlet valve 27, 28) is closed.

25. The method according to claim 23 or 24, characterized in that the determined number (ab, N _Auf ) is compared with a maximum permitted numerical value (Nab *, N _Auf *), which according to the formula

Nb * = f.- • auf or N _aU f = f _B • T ^ is formed, where f _B denotes a maximum permitted control frequency and Taf / Tab the duration of the pressure rise or fall phase,

and that when the maximum permissible numerical value (Nab *, N _ÄU f *) is _exceeded, an excessive activation of the pressure control valve (inlet valve 17, 18, outlet valve 27, 28) serving to build up or reduce the pressure is concluded.

26. The method according to claim 22 to 25, characterized in that the pressure control valves (17, 18; 27, 28) are designed as electromagnetically controllable valves and that the electrical variable is an electrical current to be supplied to the electromagnetic drive.

27. The method according to claim 22 to 25, characterized in that the pressure control valves are designed as piezoelectrically controllable valves and that the electrical variable is an electrical voltage to be applied to the piezo drive.

28. The method according to claim 25 and 26, characterized in that the correction of the dependence of the drive current

I (Δp) from the differential pressure (Δp) according to the formula

I (Δp) ^πeu = I (Δp) ^alt - Δl occurs,

where I (Δp) ^aIt the value of the dependence of the control current I (Δp) on the differential pressure (Δp) at the current operating point (Δp) before the correction (reduction) is carried out and I (Δp) ^πeu the value of the dependence of the control ^current I (Δp ) from the differential pressure (Δp) after performing the correction (reduction).

29. The method according to claim 25 and 27, characterized in that the correction of the dependence of the voltage to be applied U (Δp) on the differential pressure (Δp) according to the formula

U (Δp) ^new = U (Δp) ^old - ΔU occurs,

where U (Δp) ^{alt is} the value of the dependence of the control voltage U (Δp) on the differential pressure (Δp) at the current operating point (Δp) before the correction (reduction) and U (Δp) " ^{eu is} the value of the dependence of the control voltage U ( Describe Δp) from the differential pressure (Δp) after the correction (reduction) has been carried out.

30. Control system for carrying out the method for controlling an electronically controllable brake actuation system according to one of the preceding claims, characterized in that a pressure regulator (40) is provided, to which a pressure setpoint (Psoll) as input variables • ^mιt one of the wheel brakes (7.8 ) of the vehicle, an actual pressure value (Pist) ^with one of the wheel brakes (7, ⁸ ) of the vehicle and the hydraulic differential pressure value (Δp) applied to the pressure control valve (17, 18; 27, 28) under consideration are supplied and its output variable is the setpoint (I _So ιι or U _So ιι) of the electrical variable used to control the pressure control valve (17, 18; 27, 28), and that means (45,46) for correcting (adaptation) the Dependence of the electrical variable (I or U) on the differential pressure value (Δp) are provided.

31. Control system according to claim 30, characterized in that the pressure regulator (40) from a linear regulator (41), a pilot control module (42) and a correction module (45, 46) The linear controller (41) is supplied with the control deviation (ΔPR) formed from the pressure setpoint (P _So ιι) and the actual pressure value (Pι _s ) as an input variable, while the pilot control module (42) is connected to the pressure control valve ( 17, 18; 27, 28) applied signal representing hydraulic differential pressure (Δp) is supplied, the pilot module (42) having a pilot value

(Isoii.v / U _So ιι, v) to control the pressure control valve

(17, 18; 27, 28) used electrical quantity (I, U), which corresponds to the opening point of the pressure control valve (17, 18; 27, 28) and to the output variable (Isoii, - .; U _SO II,) of the linear controller (41) to form the setpoint (I _So ιι, Usoii) to control the pressure control valve

(17, 18; 27, 28) is added and the correction module ( _{45, 46} ) is supplied with the input values of the 1st pressure value (P _Igt ) and the differential pressure (Δp) applied to the considered (to be identified) pressure control _valve and its output variable (K _X , K ₂ ) the behavior of the pilot control module

(42) influenced.

32. Control system according to claim 31 for performing the

Method for controlling an electronically controllable brake actuation system according to one of the preceding claims 1 to 21, characterized in that the output variable (K _x ) of the correction module (45) as a difference:

K _x = I (Δp) ^πeu - I (Δp) ^aI or

K _α = U (Δp) ^πeu - U (Δp) ^{al is} defined, where

I (Δp) ^alt or U (Δp) ^aIt the value of the dependence of the electrical control ^variable I (Δp) or U (Δp) on the differential pressure (Δp) at the current operating point (Δp) carrying out the correction (adaptation) and I (Ap) ^"eu or U (Ap) denote the ^new value of the electrical control variable I (Ap) and U (Dp) from the differential pressure (Ap) after carrying out the correction (adaptation) ,

33. Control system according to claim 31 for performing the

Method for controlling an electronically controllable brake actuation system according to one of the preceding claims 18 to 24, characterized in that the correction module (46) is additionally supplied with the pressure setpoint (P _So ιι) as an input variable and that its output variable K ₂ = -ΔI from the comparison the determined number of driving operations (Nb, N _{OP of} f) (, N _on N ^ * *) is a maximum permissible value derived, in which on exceeding the maximum permitted speed value (N ^ *, N _at *) dependence of the electrical variable is lowered.