EP0906209A1

EP0906209A1 - Hydraulic motor vehicle braking system with electronic anti-lock control and circuit for such a braking system

Info

Publication number: EP0906209A1
Application number: EP97921800A
Authority: EP
Inventors: Hans-Jörg Feigel; Ronald Bayer; Johann Jungbecker
Original assignee: ITT Manufacturing Enterprises LLC
Current assignee: Continental Teves AG and Co OHG
Priority date: 1996-06-19
Filing date: 1997-04-26
Publication date: 1999-04-07
Also published as: JP4138881B2; WO1997048584A1; DE19624331B4; DE19624331A1; JP2001504055A; US6193328B1

Abstract

The essential components of a hydraulic braking system with electronic anti-lock control are a pedal-actuated brake master cylinder (1), electrically operable inlet and outlet valves (EV1 to EV4, AV1 to AV4), wheel sensors (S1 to S4) and an electronic control circuit (6). The brake master cylinder (1) is fitted with one or more travel sensors (5) for the direct or indirect detection of the pedal travel (S). Depending on the current driving situation, the braking situation and the pedal travel (S), the anti-lock control is switched over from a standard control mode of the safety control mode, which essentially permits a build-up of braking pressure in the front-wheel brakes and a release of braking pressure in the rear-wheel brakes during an anti-lock control process. Depending on the driving and braking situation, a limit (Splimit) is set for the pedal travel; when this limit is exceeded, the system changes over to the safety control mode.

Description

Hydraulic motor vehicle brake system with anti-lock control and circuit arrangement for such a brake system

The invention relates to a hydraulic motor vehicle brake system with electronic anti-lock control, with a pedal-operated brake pressure transmitter, with electrically actuable pressure medium inlet valves and outlet valves inserted into the pressure medium paths, with which the pressure medium inflow into the wheel brakes of the individual wheels and the pressure medium outflow into a pressure compensation tank the brake system can be controlled individually, with wheel sensors for determining the turning behavior of the wheels and with an electronic control circuit for evaluating the sensor signals, for recording the driving situation and for generating brake pressure control signals.

A circuit arrangement for a brake system with electronic anti-lock control also belongs to the invention.

Anti-lock braking systems or anti-lock braking systems (ABS) are available in a wide range of types. Hydraulic systems in which the wheel brakes of the individual wheels on electrically operated hydraulic valves are connected to a multi-circuit brake pressure transmitter or master cylinder have proven particularly successful are connected. In the pressure medium path from the master cylinder to the wheel brake there is an inlet valve which is switched to passage in the basic position and which is switched over to locks in the constant maintenance or pressure reduction phase. A blocked in the rest position, switchable to passage outlet valve is located in a return line which leads from the wheel brake to the low pressure accumulator or - in the open systems - to the surge tank of the brake system. Depending on the system, a return pump (in closed systems) or a hydraulic pump delivering from the pressure expansion tank to the brake circuits (in open systems) is used to return the pressure medium derived in the pressure reduction phase.

The reduction in the production outlay for such anti-lock braking systems (ABS) by simplifying the systems and components, skillful construction of the hydraulic brake circuits, by dispensing with components and by transferring functions to the associated electronics has long been the subject of intensive development. These efforts are fundamentally limited by the fact that extremely high reliability is expected from a brake system even under unfavorable, rarely occurring circumstances. "Exhaustion" of the pressure medium volume required for effective braking - as a result of frequent, long-lasting pressure reduction on slippery roads or of rapidly changing road conditions - must of course be avoided in order to maintain the brake function.

An important cost factor of such anti-lock braking systems is the hydraulic pump with the associated electric motor drive. It has therefore already been proposed to implement a pumpless ABS. An example of this is the brake system known from DE 31 09 372 AI, which provides for anti-lock control via the exhaust valves to remove discharged pressure medium in a low-pressure accumulator, from which it can then flow back into the brake circuits after the brake is released. This known system contains two brake circuits with a diagonal brake circuit division, in which each brake circuit is equipped with a common inlet / outlet valve arrangement and also with a further electrically switchable inlet valve which is inserted in the pressure medium path leading to the rear wheel brake . This inlet valve can be switched to its blocking position depending on the anti-lock control and depending on the load. A complete independence of the regulation of all wheels is therefore not given.

Furthermore, from DE 43 34 838 AI (P 7571) a two-circuit hydraulic brake system with anti-lock control is known, in which the pressure medium derived from the wheel brakes in the brake pressure reduction phase is obtained in low-pressure accumulators, which have two separate inputs for have the connection of a rear wheel and a front wheel. When a predetermined filling level of the reservoir is reached, the pressure medium inflow from the front wheel brake and thus a further pressure reduction at the front wheel brake is blocked. Up to this point there were hardly any restrictions on the ABS function, although the volume throughput was drastically reduced with the aid of special control algorithms. When a blockage of a front wheel is detected, the control algorithm for the rear axle is switched over and blockage of the rear axle is avoided (safety control mode). The maintenance of the brake function is ensured by the limited volume absorption of the low pressure accumulator.

The object of the present invention is now to develop a pumpless ABS of this type which can be used without the pressure accumulator gets by and that, even in unfavorable situations, has the required high functional reliability.

It has been shown that this object can be achieved with a motor vehicle brake system of the type described in claim 1, the special feature of which is that one or more displacement sensors for direct or indirect detection of the displacement and / or the position of the pedal and / or There are pistons of the brake pressure sensor that the anti-lock control can be switched from a standard control mode to a safety control mode depending on the current road or roadway situation, the braking situation and the feed or the position of the pedal or the piston and that in the safety control mode, the brake circuit reduces, delays or even blocks a further reduction in brake pressure in the front wheel brakes and a further increase in brake pressure in the rear wheel brakes during an anti-lock control process.

According to the invention, a pumpless ABS is thus realized on the basis of an open system, which comprises one or more pedal travel sensors and which, by switching over to a safety control mode when certain conditions are present, enables and at the same time ensures a "completely" ABS control that the brake function is retained even under very unfavorable conditions.

According to a particularly advantageous exemplary embodiment of the invention, a limit value for the pedal feed is determined as a function of the current driving (train) situation, the brake situation and the pedal travel, the switchover from the standard control mode to the safety rule being exceeded when this limit value is exceeded Mode. The limit value is expediently specified as a function of the current vehicle deceleration, taking into account the volume absorption characteristic of the respective wheel brake. However, it is also possible and in many cases advantageous to determine the limit value of the pedal feed as a function of the pedal position when the anti-lock control is used and as a function of a pedal travel available for the control according to the relationship

SpGrenz ⁼ S _p g _tart + Sp _Reg> .

Further, particularly advantageous exemplary embodiments of the invention are described in the subclaims.

Furthermore, a circuit arrangement for a brake system of this type is specified in claims 10-17, which can in principle be used advantageously for pumpless ABS with low-pressure accumulator. This circuit arrangement could also increase the functional reliability of an ABS equipped with a hydraulic pump, e.g. by ensuring the brake function in extremely unfavorable situations for which the auxiliary pressure supply or the hydraulic pump is not designed or is not sufficient.

Further features, advantages and possible uses of the invention will become apparent from the following description of further details with reference to the attached figures.

Show it:

1 shows a schematic representation of the most important components of an anti-lock brake system according to the invention and 2 in the diagram the dependence of the pedal travel and the pedal limit values on the vehicle deceleration in a brake system according to FIG. 1.

In the embodiment of the invention according to claim 1, the motor vehicle brake system consists of a brake pressure transmitter 1, which is designed here in the form of a tandem master cylinder 2 with an upstream, pedal-operated (pedal 7) vacuum booster 3. The brake system also includes a surge tank 4 and a pedal travel sensor 5.

In the pressure medium paths or brake circuits I, II, via which the wheel brakes of the front wheels VL, VR and the rear wheels, HR, HL are connected in a diagonal brake circuit division, there are electrically actuated inlet valves EV, bis in the rest position or basic position EV ₄ . Via closed in the basic position, exhaust valves AV _j to AV ₄ are the wheel brakes of the individual wheels VL, VR,

HR, HL connected to the surge tank 4 of the brake pressure sensor 1. In contrast to known anti-lock braking systems of this type, the brake system shown does not require an auxiliary pressure supply system or any hydraulic accumulators.

Each wheel VL, VR, HL, HR is equipped with a wheel sensor SI to S4, which in a known manner delivers a signal representing the turning behavior of the wheel to the inputs E of a control circuit 6. This control circuit 6 symbolizes a hard-wired or - preferably - a program-controlled circuit arrangement based on microcontrollers, which processes the wheel signals supplied by the wheel sensors SI to S4 and generates brake pressure control signals by data processing. These are via outputs A. individual intake and exhaust valves EV ₁ to EV ₄ and AV ₁ to AV _{4 connected} to the control circuit 6.

According to the invention, an "open" hydraulic system is used, in which pressure reduction or pressure medium discharge into a pressure expansion tank is fundamentally possible without restriction. A pedal travel sensor 5 is therefore necessary in order to be able to detect the maximum permissible pedal travel or the maintenance of a sufficient residual volume.

The displacement sensor 5 can advantageously be accommodated in a controller unit flanged to the master cylinder to avoid external cable routing. For example, the axial advance of the pedal linkage or a piston can be magnetically sensed with the aid of Hall sensors if such a displacement sensor is inserted into a corresponding recess in the wall of the master cylinder.

With such an open system in conjunction with the displacement sensor, a brake system with particularly high functional reliability can be implemented. The following examples are intended to explain this:

If an exhaust valve is leaking, this can be recognized in the brake system according to FIG. 1 as follows: (1.) The vehicle deceleration determined by evaluating the wheel sensor signals is assigned to a pedal position provided with a tolerance band. If the pedal position determined with the displacement sensor 5 lies outside this tolerance band, there is a fault in the brake system. This error can also be a poor bleeding condition of the brake system. (2) The wheel slips of all wheel brakes are compared. In the event of a circle failure, the slip values of the wheels of the failed circle have lower values.

(3) The rear brake inlet valve is closed and the following is observed:

(a) The wheel slip of the rear wheel decreases, the wheel slip of the front wheel increases if the pedal position is increased further, or:

(b) the wheel slip of the rear wheel remains constant, the wheel slip of the front wheel does not increase proportionally if the pedal position is increased further, or:

(4) applies (a), the inlet valve of the rear wheel brake remains closed and the warning lamp is activated. The outlet valve is actuated several times to flush out any dirt particles that may be present. If no improvement can be achieved, the associated inlet valve is then closed each time the brake is actuated. For example, a sealing sleeve of the wheel brake may also be defective. The effect for the driver will be: he has a shorter pedal and can still apply three wheel brakes - even if one wheel brake cylinder seal has failed. In contrast to a corresponding closed system, in which the failure of a wheel brake seal leads to a total failure of the circuit, this system has significantly better conditions because of the shorter pedal travel and the better braking effect by means of the three wheel brakes. The open system is therefore safer than a corresponding closed hydraulic system.

The same applies to case (b), in which the inlet valve of the front wheel is then closed. If there is no improvement in braking behavior afterwards, the master cylinder sleeve may be defective. The warning lamp is activated. 2 serves to illustrate the basic mode of operation of the brake system according to the invention. It is the pressure p _II7 , depending on the pedal force F, the pedal travel or the pedal feed S depending on the vehicle deceleration b _T7 . reproduced. The difference between the two curves S _p = f (b _FZ ) and S _pGren2 = f (b _FZ ) shown, as will be explained in more detail below, represents the pedal travel S _pRe "available for the control Relationship between the vehicle _deceleration b _rz and the brake pressure p specified. The empirically or arithmetically determined limit value of the pedal feed S _pGren2 . depending on the vehicle _{deceleration,} taking into account or adding the pedal travel S _pReg made available for the _{anti-lock control system} . The difference between S _pmax and S _p- stop, which can be seen in the _{illustration,} takes into account manufacturing tolerances, measurement errors and other deviations of different types.

The following situation examples illustrate the operation of the brake system according to the invention:

1. Braking on a road with a homogeneous, high coefficient of friction (μ _highh om) ^:

The brake pedal is operated by the driver with full foot force F. The brake pressure rising due to the filling of the wheel brakes reaches the blocking pressure level. The blocking tendency of the wheel in question is recognized from the wheel turning behavior and, via the control circuit 6 (FIG. 1), leads to the activation and blocking of the intake valve EV in question. If pressure reduction is required to restore wheel stability, additional Lent the associated exhaust valve AV for the calculated period of time or switched to passage.

This is followed by an ABS control which is expediently designed in such a way that it manages with the lowest possible volume throughput or volume outflow - of course without impairing the anti-lock control system.

The brake pedal movement during this braking process is detected and evaluated with the help of the displacement sensor 5; Expediently, the associated electronics are also accommodated in the control circuit 6.

As long as the vehicle is braked with the maximum possible deceleration (b _FZ ), which is to be expected in the present case of a braking operation with a homogeneous, high coefficient of friction, it is only necessary to ensure that the pedal _advance does not exceed a predetermined maximum value S _pmax . The feed up to the stop of the main cylinder pistons is designated in the diagram according to FIG. 2 with S _stop . If this feed or pedal travel is reduced by a safety _distance , which takes into account, among other things, the manufacturing tolerances, the maximum permissible feed or pedal travel S _{pmax is obtained} .

If the feed or the pedal reaches this feed or this position S _pmax at maximum deceleration, measures are taken according to the invention which have the effect that the pressure in the wheel brakes of the front wheels is no longer or only very slightly reduced. The easiest way to do this is to block the exhaust valve actuation or at least limit the actuation times of these front wheel exhaust valves accordingly. In addition, because the aforementioned limit value has been reached, the anti-lock control on the rear wheels is restricted. Only a brake pressure reduction in the rear wheel brakes is permitted to ensure the driving stability of the vehicle. The simplest way to achieve this goal is to control the intake valves EV, namely by blocking these intake valves.

According to the invention, when the limit value S _pGrenz is reached, the _anti- lock control is switched from the standard control mode, in which a brake pressure reduction and re-increase is permitted in both the front and rear brakes, into a safety control mode. In a first approximation, this safety control mode only allows unhindered brake pressure build-up on the front wheels and brake pressure reduction on the rear wheels, as previously explained, in order to ensure that the braking effect and driving stability are brought about without or with at most very little pressure medium consumption.

2. Braking on a road with a homogeneous, low coefficient of friction (μiow _h om):

The braking process starts again with a "normal" ABS control; the standard rule module applies.

The vehicle can only be braked with a slight deceleration b _{fZ due} to the low coefficient of friction. Due to the low pressure, there is only relatively little brake fluid in the wheel brakes. A change to a roadway with a higher or maximum coefficient of friction (U _h i _gh ) can be expected at any time; in any case, this higher coefficient of friction should be wholly or at least one a large proportion can be used for the braking process without the maximum pedal travel S _{pmax being} exceeded.

This means that the pressure medium volume required for this must be stored in the master cylinder. According to the invention, the control is therefore designed in such a way that with a relatively low vehicle deceleration b _FZ - see FIG. 2 - the ABS control is not maintained until the maximum pedal position S _pmax is reached. This is shown by the course of the curve S _pGrenz as a function of the vehicle _deceleration b _h _ in FIG. 2.

The pedal position from which the ABS control is restricted when the coefficient of friction is low is S _pGϊ . _{called enz} .

This value S _pGrenz is based on the current vehicle deceleration b _FZ and on the volume absorption characteristic of the

Wheel brakes dependent; approximately the course shown in FIG. 2 results.

The feed or pedal value limit value Spr ,,,.,!, According to FIG. 2 can be calculated as follows:

The feed or the pedal position when an anti-lock control system is used is designated S _pStart . For the

Regulation, an additional pedal travel S _pReg is made available. This pedal travel corresponds in first approximation Nä¬ the difference between the maximum pedal travel S _p m _ax ^unc * pedal position upon reaching the Blockier¬ pressure levels at a high homogeneous coefficient of friction. This pedal path is designated S _ph i _block in FIG. 2. For the

The pedal limit value s p _{limit therefore} applies to the relationship

SpGrenz S _p s _tart + S _pmax Sphighblock The difference S _pmax - S _phighblock approximates the pedal travel made available for the control - see FIG. 2.

If the feed reaches the position s p _limit , according to the invention - as before - a _switch is made from the standard control mode to the safety control mode. The control of the valves ensures that practically only brake pressure build-up on the front wheels and only brake pressure build-up on the rear wheels - apart from smaller corrective measures - is permitted or takes place.

If the coefficient of friction μ _lo remains the same, this becomes

Vehicle braked with almost optimal deceleration while maintaining steering ability and driving stability. If the slip is significantly too low as a result of the change to a higher coefficient of friction, the brake pressure is increased further in the brake system according to the invention, but is no longer or at most reduced to a small extent on the front axle.

3. Braking on lanes with different friction coefficients right / left (μs _p ii _t ) ^:

Initially, braking is again subject to the standard control mode.

As a consequence of the μ _Sp n _t situation, the vehicle can only be braked according to the friction coefficients with a medium deceleration. The wheel brakes are filled with brake fluid to different degrees. A change to a higher or even maximum coefficient of friction on the side of the road where the coefficient of friction is currently low can be expected at any time. Of course, how- which is why the higher coefficient of friction can be used for braking. This means that the brake fluid volume required for this must be present in the master cylinder. According to the invention, no unrestricted ABS control up to the maximum feed S _{pmax is therefore} permitted even in this driving situation.

For the permissible feed, the limit value ^s _{pGrenz '} ^w i ^e Fig. 2 again applies, the vehicle deceleration b _FZ , which is higher in comparison to a braking operation with a low coefficient of friction (μι _ow ), leads to a higher one permissible feed or pedal travel limit value SpGrenz •

The previously (μι ₀₎ in connection with a braking operation on ge ringem friction coefficient calculation of the pedal-travel threshold value S zu¬ permeable _pGren2 described also applies to the present μ _Spl i _t situation.

When the permissible pedal position S _{pGr is reached} . As previously described, _enz is in turn switched from the standard control mode to the safety control mode.

If the coefficient of friction on the right / left remains the same, the vehicle equipped with the brake system according to the invention is braked to a standstill with almost optimum deceleration while maintaining the steering ability and driving stability. If, as a result of a change to a higher coefficient of friction, the brake slip is clearly too low, the brake pressure on the front axle is increased further, but can no longer be reduced. When using a brake system with a tandem master cylinder, it is fundamentally possible to detect and evaluate the movement of both pistons with the aid of individual displacement sensors. A feed limit value S _pGrenz is then individually determined for each piston, which is _decisive for the transition or the changeover from a standard control mode to a safety control mode.

In many cases, however, it will be sufficient and, for reasons of economy, only to detect the advance of the push rod piston of a tandem master cylinder with the aid of the displacement sensor 5 (FIG. 1). A different volume consumption in the two brake circuits of the tandem master cylinder cannot, of course, be determined solely on the basis of the feed measurement of the push rod piston. Therefore, by detecting and evaluating the valve switching times, in particular the passage time periods of the intake valves EV, the different volume consumption can be approximately determined during an anti-lock control process. In this case, the maximum possible deviation of the estimated value from the actual value can be taken into account and a possible error can be compensated for by a higher safety margin in the calculation or empirical determination of the limit value S " _G , _P " ₂ .

It has already been pointed out that a circuit arrangement of the type described here which permits the determination and consideration of a maximum permissible pedal limit value S _r , _n ,,. ", And a switchover from a standard control mode to a safety rule Mode when this limit value is reached or exceeded, could also be advantageous for anti-lock brake systems which are equipped with a hydraulic pump and / or with pressure accumulators. Such measures could be used in special Increase the functional reliability of the brake system without significant additional manufacturing or manufacturing effort.

Claims

Hydraulic motor vehicle brake system with electronic anti-lock control, with a pedal-operated brake pressure transmitter, with electrically operated pressure medium inlet valves and outlet valves inserted into the pressure medium paths, with which the pressure medium flow into the wheel brakes of the individual wheels and the pressure medium outflow into a pressure compensation tank the brake system can be controlled individually, with wheel sensors for determining the turning behavior of the wheels and with an electronic control circuit for evaluating the sensor signals, for detecting the driving situation and for generating brake pressure control signals, characterized in that one or more paths ¬ sensors (5) for direct or indirect detection of the path and / or the position of the pedal (7) and / or pistons of the brake pressure sensor (1) are available, depending on the current road or road situation, the braking situation and the Feed or position of the Pedals (7) or the piston, the anti-lock control can be switched from a standard control mode to a safety control mode and that in the safety control mode the control circuit (6) reduces brake pressure in the wheel brakes of the Front wheels (VL, VR) and / or a build-up of brake pressure in the wheel brakes of the rear wheels (HL, HR) is restricted, delayed or blocked during an anti-lock control process.

Motor vehicle brake system according to claim 1, characterized in that the control circuit (6) determines a limit value (S p _limit ) of the pedal advance as a function of the current road or roadway situation and braking situation and that when exceeded this limit value (S p _limit ) the switchover from the

Standard control mode takes place in the safety control mode.

Motor vehicle brake system according to claim 1 or 2, characterized in that the limit value (S _pGrβnz ) of the

Pedal feeds depending on the pedal position (S) when the anti-lock control is activated (S _pStart ) and on a pedal travel available for the control (S _{pReg #} ) according to the relationship

SpGrenz ⁼ Spgtart + SpReg. is specified.

Motor vehicle brake system according to claim 3, characterized ge indicates that the pedal travel available for the control (S _{pReg #} ) from the difference between the maximum permissible pedal feed (S _praax ) and the

_Pedal travel (S _phighblock ) with maximum deceleration of the

Vehicle can be determined.

Motor vehicle brake system according to claim 1 or 2, characterized in that the limit value of the pedal feed (S _pGrβnz ) as a function of the current vehicle deceleration (b _FZ ) taking into account the

Volume absorption characteristic of the respective wheel brake is specified.

Motor vehicle brake system according to one or more of claims 1 to 5, characterized in that as long as the limit value (S p _limit ) of the pedal travel or the

Pedal position is exceeded, a pressure medium outflow via the outlet valves (AV _1; ") of the front wheel brake is blocked or only permitted up to a limited amount.

7. Motor vehicle brake system according to one or more of claims 1 to 6, characterized in that, as long as the limit value (S _pGren2 ) of the pedal travel or

Pedal position is exceeded, a pressure medium flow through the inlet valves (EV ₂ ,) of the rear wheel brakes is prevented or limited to a predetermined value.

8. Dual-circuit motor vehicle brake system according to one or more of claims 1 to 7, with a tandem master cylinder as a brake pressure sensor, characterized gekenn¬ characterized in that only a displacement sensor (5) is provided for detecting the feed and / or the position (S) of the push rod piston , and that for the approximate determination of different pressure medium volume consumption in the two hydraulic circuits (1, 11) of the brake system, the activation times of the inlet valves (EV _lf4 ) during a regulated

Brake processes are recorded and evaluated.

9. Two-circuit brake system according to one or more of claims 1 to 7, with a tandem master cylinder as a brake pressure sensor, characterized in that both pistons of the tandem master cylinder are equipped with displacement sensors and that an individual feed limit value for each brake circuit (S p _limit ) can be determined.

10. Circuit arrangement for a brake system with electronic anti-lock control, with wheel sensors and with pedal travel sensors, with electronic circuits for evaluating the sensor signals and for generating Brake pressure control signals, characterized in that a limit value (S _pGrenz ) for the feed or the position of the

Pedal (7) or a corresponding measured variable is determined and that when the limit value ( ^s _pG limit) is exceeded, the anti-lock control is switched from a standard control mode to a safety control mode, with the safety control mo ¬ a (further) brake pressure reduction in the front wheel brakes and / or a further brake pressure build-up in the rear wheel brakes is restricted, delayed or prevented during the anti-lock control process.

11. Circuit arrangement according to claim 10, characterized gekenn¬ characterized in that the safety control mode is maintained as long as the pedal travel (S) is above the limit value (S p _limit ).

12. Circuit _arrangement according to claim 10 or 11, characterized in that the limit value (S _pGrenz ) of the Pedal¬ feed (S) as a function of the pedal position when the anti-lock control (S _pStΛ ,,) and one available for the control _Pedal travel (S _pReg .) According to the relationship

SpGrenz ⁼ Spgtart ⁺ S _{pReg # is} specified.

13. Circuit arrangement according to claim 12, characterized in that the pedal travel available for the control available (S _pReg ) from the difference between the maximum permissible pedal feed (S _pmax ) and the pedal travel at maximum vehicle deceleration is determined.

14. Circuit _arrangement according to claim 10 or 11, characterized in that the limit value (S _PGrenz ) is given as a function of the current vehicle deceleration (b _F7 ) taking into account the volume absorption characteristic or characteristic curve of the respective wheel brake.

15. Circuit arrangement according to one or more of claims 10-14, characterized in that there are programm-controlled or hard-wired circuits which compare the instantaneous pedal and / or piston position with the vehicle deceleration derived from the rotational behavior of the wheels and evaluate the exceeding of predetermined limit values or a predetermined tolerance band as a criterion for recognizing a leak or a poor state of ventilation of the brake system.

16. Circuit arrangement according to one or more of claims 10-15, characterized in that there are program-controlled or hard-wired circuits which compare the wheel slip values of the wheels connected to various hydraulic brake circuits and which prevent the occurrence of wheel slip differences. which indicate a leak in a brake circuit or a poor state of ventilation.

17. Circuit arrangement according to one or more of claims 10-16, characterized in that programm-controlled or hard-wired circuits are present which detect and / or change the wheel. Determine and evaluate slip as a function of the valve control and, if there is typical behavior for the presence of dirt particles, cause the dirt particles to be rinsed out by repeated, brief activation of the associated outlet valves.