EP3055174A1

EP3055174A1 - Method for operating a braking system and a braking system

Info

Publication number: EP3055174A1
Application number: EP14739136.1A
Authority: EP
Inventors: Andreas Neu; Thorsten Ullrich; Tobias Scheller; Robert Schmidt; Joachim Borneis; Benjamin Jüstel; Patrick Henke
Original assignee: Continental Teves AG and Co OHG
Current assignee: Continental Teves AG and Co OHG
Priority date: 2013-10-11
Filing date: 2014-07-10
Publication date: 2016-08-17
Also published as: KR20160070177A; WO2015051929A1; US20160236662A1; CN105705390A; DE102013220582A1

Abstract

The invention relates to a method for operating a brake system of a vehicle which comprises a master brake cylinder (4) which can be activated by the driver by means of a brake pedal (1), at least one driver-independent pressure source (11), at least one wheel brake (9a, 9b) to which a wheel speed sensor is assigned, and a brake activation sensor (5), wherein it is checked whether a hazardous situation is present, and in the case of a hazardous situation being detected the at least one driver-independent pressure source (11) is activated. According to the invention, a hazardous situation is detected when the change in a measured deceleration (a) over time or the absolute value of a measured deceleration (a) exceeds a predefined hazard threshold value (a_ctive) and a brake activation operation is detected. In addition, the invention relates to a brake system for a motor vehicle having brake assistance in hazardous situations ("brake assistant") which does not require a master brake cylinder pressure sensor.

Description

METHOD FOR OPERATING A BRAKING SYSTEM AND A BRAKING SYSTEM

The invention relates to a method according to the preamble of claim 1 and a brake system according to the preamble of claim 12.

The term "brake assist" systems for braking ^¬ support the driver are known, which provide a rapid pressure buildup on detection of a dangerous situation until a brake slip control engages and the present coefficient of friction is thus optimally utilized For a brake assistant of this kind, as is known, for example, from DE 101 37 016 A1, a pressure sensor connected to the master brake cylinder is required with regard to the brake master It is imperative that driving safety be prevented by the erroneous activation of a brake assist (eg due to a faulty sensor ^signal ) Redundant pressure sensors that prevent incorrect activation cause high costs.

The DE 10 2008 036 607 Al discloses a process for the hydrau ^¬ metallic brake pressure gain in a hydraulic motor vehicle brake system, wherein a first portion of a pressure

Brake pressure is generated in the brake system driver-controlled, in which detects a pointing to a deceleration of the vehicle delay value and a second additional pressure component is generated in dependence on the delay value. The second pressure component is preferably produced in such a manner that it is proportional to the first pressure portion in Wesent ^¬ union. A Redun ^¬ dante and thus protected against errors detection of an emergency To provide braking situation, a plausibility check of a simple pressure sensor expediently takes place by comparing the measured pressure with a pressure value determined from the vehicle deceleration.

From WO 2011/107301 AI a method for performing an emergency braking operation is known, in which a driver by ^¬ given brake operation is enhanced by a brake assist system, the shutdown of the brake booster is performed in at least two stages. In the beschrie ^¬ surrounded method detecting a Bremsassistent- the system activating emergency situation is preferably carried out without pressure sensor. An explanation of how a faulty activation without pressure sensor can be reliably prevented, is not given in this document.

Object of the present invention is therefore to provide a method for operating a brake system or a brake system which be ^¬ riding provides the driver a reliable brake assist even without a measurement of the pressure in the master brake ^¬ cylindrical and in particular an erroneous activation ver ^¬ avoids.

This object is achieved by a method according to claim 1 and a brake system according to claim 12.

There is thus a method for operating a braking system is provided which comprises a driver operable means of a brake ^¬ pedals master brake cylinder, at least one driver-independent pressure source, at least one wheel brake associated with a wheel speed sensor, and a brake operation ^¬ sensor, in particular a brake light switch, wherein It is checked whether there is a dangerous situation and in the In the event of a detected dangerous situation, the at least one driver-independent pressure source is activated. According to the invention, a dangerous situation is detected when the temporal gradient or the amount of a measured deceleration exceeds a predetermined danger threshold and a brake actuation is measured.

By detecting a dangerous situation based on the signals of at least two independent sensors, a first sensor for measuring a deceleration and a second sensor for detecting a brake application by the driver, erroneous activation is reliably prevented. For example, if the driver drives up an incline and releases the accelerator pedal, the resulting deceleration can be interpreted as braking in principle. But as long as there is no operation of the brake pedal in this situation is not expected from a Gefah ^¬ rensituation. The inventive method therefore prevents dangerous for subsequent traffic groundless emergency stop the vehicle. If, on the other hand, plausible signals from the independent sensors indicate a driver's panic braking or a dangerous situation, the driver is assisted with a hydraulic pressure build-up. Therefore, in case of danger, a reaching out ^¬ braking force is ready to brake the vehicle in a short time to a standstill. Thus, a reliable implementation of a brake assist is ensured without a pressure sensor in the brake circuit or brake system is required. The measured delay is preferably determined from the signals of at least one wheel speed sensor required for a brake slip control, and a brake actuation is measured on the basis of the brake light switch. These sensors are reasonably priced and ^¬ due to legal requirements (such as ECE R13H) already present. The brake actuation sensor can be used as element or analog or multi-step displacement sensor be realized and be arranged on the brake pedal or on the tandem master cylinder.

It is advantageous when the braking system at least two, includes the wheel brakes ^¬ particular four, which is respectively associated with a wheel speed sensor, and when the measured delay from the signals of at least two wheel speed sensors is determined. When using several sensors to measure the delay, averaging is advantageously carried out. Alternatively or additionally, a low-pass filtering and / or a comparison of filtered wheel speed signals with unfiltered wheel speed signals can take place. This facilitates the selection of appropriate threshold values for the adjustment to the respective vehicle and vehicle model to provide a schnellstmög ^¬ possible support in the event of danger at the same time robustness against false positives. In particular, it is advantageous to consider the signals from being ^¬ arranged on the front wheel speed sensors.

It is particularly advantageous if a first delay from the signals at least a first wheel speed sensor is in the presence of a plurality of wheel speed sensors is determined and a second delay from the signals at least a two ^¬ th sensor is determined, wherein only a danger Situational ^¬ tion is detected when both is the temporal gradient or the amount of the first delay as well as the temporal gradient or the amount of the second delay exceeds the predetermined danger threshold. For example, can be regarded as ^¬ probably a vehicle deceleration as well as one or more wheel decelerations. By such

Plausibility of the wheel speed signals can be chosen to be particularly low thresholds, without the risk of Increase false identifications.

Preferably, a dangerous situation is detected only if the time gradient or the amount of the measured delay exceeds the predetermined danger threshold value within a predetermined period of time since the detection of a brake application. By the brake actuation based on an edge of the brake light switch signal from unactivated to actuated betae ^¬ or detects a comparison of Bremswegsensorsignals with a predetermined brake detection threshold, an accurate time measurement can be done. Because only the beginning of a braking process is considered, a Panikbremssitu ^¬ tion of the driver can be detected particularly reliable.

According to a preferred embodiment of the invention, the signals of an accelerator pedal sensor are considered in addition, where ^¬ takes place at a pre-conditioning of the brake system and / or a dangerous situation is only detected if the release speed of the accelerator pedal exceeds a predetermined Panikschwel ^¬ lenwert and / or the time duration between a Release the accelerator pedal and an operation of the brake pedal falls below a predetermined reaction threshold. Since an accelerator pedal or accelerator pedal operation is often already detected by a pedal sensor, this information can be easily evaluated. Such a consideration of the precursor ^¬ layer can be advantageously used to trigger a preconditioning of the brake system, wherein a startup delay of the pump is reduced and / or by a

Prefilling the brake system without applying a name ^¬ worthy brake pressure to overcome the clearance when a quick release of the accelerator pedal indicates a dangerous situation ^¬ . Conveniently, a first solenoid valve is arranged between master cylinder and wheel brakes, which is in particular open, wherein the driver-independent pressure source comprises an electric hydraulic pump which is connected on the outlet side with the wheel brakes and the inlet side via a second solenoid valve, which is in particular currentless closed ge ^¬ can be connected to the master cylinder, and wherein an activation of the driver-independent pressure source comprises at least partially closing the first solenoid valve ^¬ and opening the second solenoid valve.

Brake systems with a vehicle dynamics control often have such solenoid valves and a hydraulic ^¬ pump in each brake circuit.

It is particularly expedient if the first solenoid valve can be actuated ana ^¬ log to maintain a predetermined Druckdiffe ^¬ rence between the master cylinder and wheel brakes, the predetermined pressure difference between the master cylinder and wheel brakes to a constant value, preferably between 30 and 60 bar, is limited. By the first solenoid valve, in particular an isolation valve opens in case of ^¬ exceed the pressure difference and thus the maximum pressure in the wheel brakes is limited, can be dispensed with Druckmes ^¬ sung in the wheel brakes. This Überströmrege ^¬ ment of the isolation valve, in which a predetermined pressure difference between the wheel and master cylinder is set, made ^¬ light a superposition of the brake pressure built up by the driver with a driver-independent pressure source. Thus, a Bremsver keep convincing with regard to driving comfort and safety ^¬ is guaranteed.

In particular, the current through the first solenoid valve is set in accordance with a characteristic curve which determines the relationship describes between valve current and pressure difference and is preferably read from a non-volatile memory. By adjusting the current based on a characteristic which has been suitably calibrated for the valve, excessive deviations between the desired and actual pressure difference can be avoided.

It is advantageous if the deceleration is repeatedly measured, and when an end of the hazardous situation detected and the driver-independent pressure source is deactivated as soon as the loading ^¬ support or the amount-related increase in the measured delay after a predetermined time period since detection of the danger situation falls below a predetermined deactivation threshold. By observing the deceleration structure at defined times, it is possible, for example, to detect a low friction coefficient of the roadway. Then the brake assistance is not required and can be stopped.

Furthermore, it is advantageous if the delay is measured repeatedly, wherein a current value of the delay is compared with a maximum value, wherein the current value of the delay is stored as a new maximum value, if the previous maximum value is smaller than the current value of the delay, and that an end of the dangerous situation is detected and the driver-independent pressure source is deactivated when the current value of the delay falls below a predetermined proportion of the maximum value. This makes it possible to recognize a ver ^¬ ringerte brake actuation by the driver, and then a brake support is no longer required.

Appropriately, an end of the dangerous situation is detected and the driver-independent pressure source is deactivated when the vehicle speed is a predetermined holding threshold falls below and / or one end of the brake operation is measured and / or the driver-independent pressure source was longer than ei ^¬ ne predetermined maximum period of time in operation. If the vehicle is stationary, the driver releases the brake pedal, or the end of the dangerous situation is due to the activation period, the brake assistance can be ended.

The invention further relates to a brake system for a

Motor vehicle having a driver operated by a brake pedal brake master cylinder, a driver-independent pressure source, in particular an electric hydraulic pump, Minim ^¬ least one wheel brake associated with a wheel speed sensor, and a brake operation sensor, in particular comprises a brake light switch. According to the invention, the brake system is driven by one end connected to the brake operation sensor electronic control unit, which provides a brake negative support alarm ^¬ Zung in dangerous situations, but is not connected to a sensor for detecting the pressure in the master cylinder. In this case, it may also be provided to carry out the brake light switch redundantly in order to ensure reliable detection of braking by the driver.

Preferably, the electronic control unit, insbeson ^¬ particular in each brake circuit, a valve disposed between the main brake cylinder and wheel brakes first solenoid valve which is insbeson ^¬ particular normally open, an electric hydraulic pump, which is the outlet connected to the or the wheel brakes, a second solenoid valve, through which the electrical Hydrau ^¬ likpumpe on the inlet side to the master brake cylinder can be connected and which is CLOSED ^¬ sen in particular de-energized, and a drive circuit for the first and the second solenoid valve, whereby in particular the drive circuit for the first solenoid valve means for controlling a target Current has. This allows a Überströmregelung of the separating valve to be superimposed on the driver's braking pressure a predetermined Diffe ^¬ rence pressure.

Preferably, the electronic control unit on a Rechenein ^¬ integrated, performs a process of the invention is where stored in a non-volatile memory in particular, the program code for carrying out the procedural ^¬ ^¬ proceedings.

Preferably, the electronic control unit comprises a

Interface for a vehicle data bus and is in particular connected to an engine control unit. Thus, e.g. also the signals of an accelerator sensor for triggering the

Brake assistance to be evaluated.

Further preferred embodiments will become apparent from the subclaims and the following description of an embodiment with reference to figures.

Show it

Fig. 1 is an exemplary brake system, and

Fig. 2 is a schematic representation of a braking operation.

Figure 1 shows an exemplary brake system of a motor vehicle, with which the inventive method is feasible. The driver-operable brake pedal 1 can be designed with or ^¬ oh ne power assistance. The braking force of the driver acts on a push rod, possibly superimposed with a built-up of vacuum brake booster 2 auxiliary power on (tandem) master cylinder 4, the in

unoperated condition with a non-pressurized brake fluid Reservoir is connected. About a brake light switch 5 can be determined whether the driver actuates the brake pedal betae ^¬ . Alternatively, the brake light switch can also be replaced by a displacement sensor which is arranged, for example, on master brake cylinder 4. The brake system includes two brake ^¬ circles I, II, where (in a four-wheeled motor vehicle) in each case two wheel brakes are assigned. In the following, only the brake circuit I is described, the other brake circuit II is constructed purpose ^¬ advantageously identical. The distribution of braking ^¬ circles, so if for example a rear ^¬ are summarized wheel brake in a brake circuit each have a front brake and is in principle irrelevant for the present process.

Master brake cylinder 4 is connected via brake lines to the wheel brakes 9a, 9b, wherein by closing a first intake valve 7a, the first wheel brake 9a or by means of a second intake valve 7b, the second wheel brake 9b can be separated from the master cylinder 4. The pressure in the first and second wheel brake can be reduced by opening the discharge valve 8a and 8b by braking liquid ^¬ ness is discharged into a low pressure accumulator 10 degrees. An electrically driven hydraulic pump 11 allows Lee ^¬ Ren of the low-pressure accumulator 10. Furthermore, the brake system has a also referred to as a separating valve analog controllable solenoid valve 6, which normally open and between

Outlet side of the hydraulic pump 11 and the master cylinder is arranged. The suction side of the hydraulic pump 11 is connected to the low-pressure accumulator 10 and can be connected via a well-known as an electronic change-over valve normally CLOSED solenoid valve ^¬ senes with the master brake cylinder. 4

At each wheel of the motor vehicle are not expediently arranged wheel speed sensors arranged, which are connected to an electronic control unit, also not shown. If the wheel speed of a wheel during braking decreases sharply, a brake slip control or

Antilock braking done by the corresponding inlet valve is closed and by opening the corresponding exhaust valve, the pressure in the wheel brake and thus the braking force is reduced. The brake slip control can take place by means of methods known per se, in which pressure buildup, pressure maintenance and pressure reduction phases repeat cyclically. The electronic control unit may also provide a yaw moment control known per se, such as e.g. in EP 0 792 229 B1. The control of the brake system for a driver-independent pressure build-up is explained below.

FIG. 2 (a) shows a schematic representation of an exemplary braking process, wherein the deceleration a is shown over the time t. Here, the solid line 100 indicates the vehicle deceleration, while the broken line 102 represents the delay corresponding to the driver's request.

If one considers the temporal change of the signals of wheel speed sensors, in particular of non-driven wheels, then the current acceleration or deceleration a of the vehicle can be determined from this. In this case, a filtering such as a low-pass filtering with a suitable time constant and / or an averaging between the signals of different wheel speed sensors may expediently also take place. At the time to the driver operates the brake, whereupon the vehicle deceleration increases according to the pedal operation. The beginning of the braking process can be based on a change of the Switching state of the brake light switch are detected.

The current deceleration a of the vehicle is interpreted as an indication of the driver's braking request and compared with the threshold 3aktiv. A dangerous situation is expediently detected when the current delay within a predetermined period of time exceeds the threshold value a _a ktiv. Al ^¬ tively or additionally the time gradient or the amount-increase over time of the delay may be compared to a predetermined threshold. If the current delay and / or the time gradient exceed the corresponding threshold value, which occurs when, for example according to the braking operation at the time ti, an additional pressure in the wheel brakes is established by closing block valve 6, switching valve 12 is opened and the pump is activated (currency ^¬ rend the intake valves 7a, 7b are open and the exhaust valves 8a, 8b are closed).

Activation of the pump causes the pressure in the wheel brakes to increase, thus increasing the vehicle deceleration (line 100) faster than the driver's desire (line 102). Appropriately, the isolation valve 6 is analogously ^¬ controls by the drive circuit of the valve applies a desired current in accordance with a valve characteristic, which is also referred to as overflow. The valve characteristic indicates the relationship between valve current of a solenoid valve and maximum pressure difference; it is conveniently determined by measuring the valve or a calibration at the end of the tape in the factory and stored in the electronic control unit. As soon as the pressure in the wheel brakes exceeds the pressure in the master cylinder by more than the desired pressure difference Δρ, the separating valve opens. In a preferred embodiment of the invention, a fixed pressure difference Δρ of, for example, 50 bar between the pressure in the master cylinder and the pressure in the wheel brakes is specified. The actual vehicle deceleration 100 is therefore k ⁺ p above the driver's request 102. The constant k is given by the design of the brake system. The fes ^¬ te pressure difference is preferably chosen so that on the one hand ^¬ a minimum delay and on the other hand, a protection of the caliper in the wheel brakes are guaranteed against overload. In an alternative embodiment of the invention, it may also be provided, based on a predetermined gain characteristic, for example, indicates a relationship between temporal gradient of the brake pedal actuation and pressure difference to be set and conveniently stored in the memory of the electronic control unit, to determine a desired pressure difference Δρ. In the period between t2 and iß the driver keeps the brake constant, which is why the vehicle deceleration remains the same.

At the time, the driver reduces the brake operation without fully releasing the brake. Therefore, the pre ^¬ given pressure difference is further superimposed, and the vehicle deceleration decreases according to the driver's request. If the driver keeps the brake actuation constant as at time t ₄ , the vehicle deceleration remains the same (in this example, a constant, high coefficient of friction is assumed).

The driver further reduces the brake operation at time ts, with the vehicle deceleration decreasing as well. Once the brake pedal is fully released, so ίβ Time ^¬ point, an end to the dangerous situation is detected and the Hydraulic pump deactivated. The changeover valve 12 is ge ^¬ closed and the isolation valve 6 is opened slowly. For the purpose ^¬ sem the desired pressure difference and the current applied to isolation valve 6 is reduced. This is done before Trains t ^¬ with a specified ramp. At time t ₇ , the pressure difference is completely reduced.

Appropriately, the maximum occurring delay a _m ax is determined during the entire braking process at predetermined time intervals. A termination of the brake assistance is preferably also when the current vehicle deceleration falls below a predetermined proportion of the maximum delay occurred. If the braking takes place on a road surface whose coefficient of friction decreases significantly, a brake slip control can intervene. The exhaust and intake valves can be controlled in a conventional manner to optimally utilize the existing coefficient of friction. Even if the driver significantly reduces his braking request, it can be detected by comparing the instantaneous deceleration with the maximum occurring deceleration that no more brake assistance is required. Furthermore, it can be provided to terminate the brake assist when a stoppage or a predetermined low speed of the elevator ^¬ zeugs was detected.

The fact that a driver-independent pressure build-up, collision accidents are avoided, which could otherwise occur due to a too ZAG ^¬ stick brake actuation by the driver who often does not fully use the existing coefficient of friction. By the pressure build-up with the help of an overflow control or an analog control of the isolation valve, the driver can continue to enter and the pressures are superimposed. The use of independent sensors also ensures a reliable plausibility check, so that it is possible to dispense with a pressure sensor on the master brake cylinder for realizing a brake assistant according to the invention.

Claims

Patent claims

1. A method for operating a braking system of a vehicle which has a master brake cylinder (4) which can be actuated by the driver using a brake pedal (1), at least one driver-independent pressure source (11), at least one wheel brake (9a, 9b), which is assigned a wheel speed sensor, and a NEN brake actuation sensor (5), in particular a brake light switch, whereby it is checked whether a dangerous situation exists, and in the case of a detected dangerous situation, the at least one driver-independent pressure source (11) is activated, characterized in that a ^dangerous situation is then recognized , when the time gradient or the amount of a measured deceleration (a) exceeds a predetermined danger threshold and a brake application is measured.

2. The method according to claim 1, characterized in that the braking system comprises at least two, in particular four, wheel brakes (9a, 9b), each of which is assigned a wheel speed sensor, and that the measured deceleration (a) from the signals from at least two wheel speed sensors is determined, in particular the signals from ^wheel speed sensors arranged on the front axle.

3. The method according to claim 1 or 2, characterized in that a first delay is determined from the signals of at least ^one first wheel speed sensor and a second delay is determined from the signals of at least a second sensor, only then a dangerous ^situation being recognized is when both the time gradient or the amount of the first delay and the time gradient or the amount of the second delay meet the predetermined exceeds the given danger threshold.

Method according to at least one of claims 1 to 3, characterized ⁱⁿ that a dangerous situation is only recognized if the time gradient or the amount of the measured delay (a) exceeds the predetermined danger threshold within a predetermined period of time since a brake actuation was detected.

Method according to at least one of claims 1 to 4, characterized in that the signals from an accelerator pedal sensor are ^also considered, with the brake system being preconditioned and/or a dangerous ^situation only being recognized when the release speed of the accelerator pedal is one predetermined panic threshold value exceeds ^¬ and / or the time period between releasing the accelerator pedal and pressing the brake pedal (1) falls below a predetermined reaction threshold value.

6. The method according to at least one of claims 1 to 5, characterized in ^that a first solenoid valve (6) is ^arranged between the master brake cylinder (4) and wheel brakes (9a, 9b), which is opened in particular without current, so that the driver is independent Pressure source (11) comprises an electric ^hydraulic pump, which is connected on the outlet side to the wheel brake(s) (9a, 9b) and can be connected to the master brake cylinder (4) on the inlet side via a second solenoid valve (12), which is closed in particular when de-energized , and that activation of the driver-independent pressure source (11) includes at least partially closing the first solenoid valve (6) and opening the second solenoid valve (12).

7. The method according to claim 6, characterized in that the first solenoid valve (6) can be controlled analogously in order to maintain a predetermined pressure difference (Δρ) between the master brake cylinder (4) and wheel brakes (9a, 9b), the predetermined pressure difference ( Δρ) between the master brake cylinder (4) and wheel brakes (9a, 9b) is limited to a constant value, preferably between 30 and 60 bar.

8. The method according to claim 7, characterized in that the current through the first solenoid valve (6) is adjusted in accordance with a characteristic curve which describes the relationship ^between the valve current and the pressure difference (Δρ) and is preferably read out from a non-volatile memory.

9. The method according to at least one of claims 1 to 7, ^{characterized} in that the delay (a) is measured repeatedly and that an end to the dangerous situation is recognized and the driver-independent pressure source (11) is ^deactivated when the amount or the amount of increase in the measured delay (a) after a predetermined period of time since the dangerous situation was detected falls below a predetermined deactivation threshold.

10. The method according to at least one of claims 1 to 8, ^{characterized} in that the delay (a) is measured repeatedly, with a current value of the delay (a) being compared with a maximum value (a _max ), the ak ^¬ current value of the delay (a) is ^saved as a new maximum value if the previous maximum value is smaller than the current value of the delay (a), and that an end de of the dangerous situation is recognized and the driver-independent pressure source (11) is deactivated when the current value of the deceleration (a) falls below a predetermined proportion of the maximum value (a _max ).

11. The method according to at least one of claims 1 to 9, ^{characterized} in that an end of the dangerous situation is recognized and the driver-independent pressure source (11) is ^deactivated when the vehicle speed falls below a ^{predetermined} stopping threshold and / or an end Brake actuation is measured and / or the driver-independent pressure source (11) was in operation longer than a predetermined ^maximum time period.

12. Braking system for a motor vehicle, comprising one of

Driver by means of a brake pedal (1) actuated master ^brake cylinder (4), a driver-independent pressure source (11), in ^particular an electric hydraulic pump, at least one wheel brake (9a, 9b), which is assigned a wheel speed sensor, and a brake actuation sensor, in particular one Brake light switch, characterized by an electronic control unit connected to the brake actuation sensor, which provides braking support in dangerous situations, but is not connected to a sensor for detecting the pressure in the master brake cylinder.

13. Brake system according to claim 12, characterized in that the electronic control device has a first ^solenoid valve (6) arranged between the main brake ^cylinder (4) and the wheel brakes (9a, 9b), which is opened in particular without current, ^an electric hydraulic pump ( 11), which is connected on the outlet side to the wheel brake(s) (9a, 9b), a second solenoid valve (12), via which the electric hydraulic Pump on the inlet side can be connected to the master brake cylinder (4) and which is in particular ^closed without current, as well as a control circuit for the first

(6) and the second (12) solenoid valve, in ^particular the control circuit for the first solenoid valve

(6) Has means for current regulation.

14. Brake system according to claim 12 or 13, characterized in that the electronic control device has a computing unit which carries out a method according to one of claims 1 to 11, in particular the program code for carrying out the method being stored in a non-volatile memory.

15. Brake system according to at least one of claims 12 to 14, characterized in that the electronic control unit comprises an interface for a vehicle data bus and is in particular connected to an engine control unit.