WO2008122469A1 - Brake system for a vehicle - Google Patents

Abstract

The invention relates to a brake system having an actuator unit (10, 10') which comprises a brake pedal (2), a pedal simulator (4), and an electromechanical brake force amplifier (12, 12'), and having a master brake cylinder (20) via which at least one wheel brake (42, 44, 46, 48) can be controlled with prespecifiable braking pressure, wherein the brake pedal (2) or the electromechanical brake force amplifier (12, 12') works on the master brake cylinder (20) in order to build up or reduce brake pressure. According to the invention, the electromechanical brake force amplifier (12, 12') works on a piston (21) of the master brake cylinder (20) during a first operation mode, preferably a brake-by-wire operation mode, said amplifier being controlled by an evaluation and control unit (11, 11'), and the brake pedal (2) is mechanically decoupled from the piston (21) of the master brake cylinder. The evaluation and control unit (11, 11') carries out a brake pressure regulating function and/or a brake slip regulating function for the at least one wheel brake (42, 44, 46, 48) via the master brake cylinder (20) under amplified brake force applied bythe brake force amplifier (12, 12'), and via a downstream pumpless fluid control block (30).

Description

 description

title

Braking system for a vehicle

State of the art

The invention relates to a braking system for a vehicle according to the preamble of independent claim 1.

A conventional braking system with an electromechanical brake booster is described, for example, in US Pat. No. 6,634,724 B2. In the described described by an electric motor driven brake booster, the rotational movement of the electric motor is converted into a translational movement to increase the braking force during operation. The conversion of the rotation into a translation takes place by means of a pinion / rack combination.

The described brake booster is part of an auxiliary power brake system in which the actual braking force is generated by a summation of a pedaling force applied by the driver and an assisting force applied by the brake booster.

In the publication WO 2005/014351 Al a so-called brake-by-wire brake system is described. The brake system described is actuated by a brake actuation unit, which comprises a brake booster, which is designed as a vacuum brake booster, a master brake cylinder connected downstream of the brake booster, means for detecting a driver's desire and a pedal travel simulator. The brake booster can be operated depending on the driver by means of a brake pedal as well as by means of an electronic control unit, wherein means are present which decouple a force-transmitting connection between the brake pedal and the brake booster during the brake-by-wire mode. Of the During the brake-by-wire mode, the pedal travel simulator simulates a restoring force acting on the brake pedal independently of actuation of the brake booster, wherein the pedal travel simulator can be engaged during decoupling of the force-transmitting connection between the brake pedal and the brake booster during the brake-by-wire mode and can be switched off outside the brake-by-wire operating mode. The switching on and off of the pedal travel simulator is performed by electromechanical, electro-hydraulic or pneumatic switching means.

Another technology known from the prior art relates to a pumpless anti-lock braking system (ABS), which can be made much simpler by omitting damper chambers and return pumps. If a tendency of the wheels to lock is detected during a braking operation, then corresponding inlet valves are closed in order to prevent further pressure build-up in the wheel brakes. If this measure is not sufficient to lift the blocking tendency, the associated exhaust valve is opened until the wheel slip decreases again, then the exhaust valve is closed again. The liquid flowing out of the associated wheel brake through the opening of the outlet valve is received by storage chambers. After reaching a stable wheel speed, the associated

Inlet valves reopened. The process described is repeated until the driver stops braking, or the vehicle has come to a standstill. After releasing the brake pedal by the driver, the brake fluid received by the storage chambers flows through storage chamber springs via the inlet valves and check valves in the

Master cylinder back. As a result, the system is ready for a new ABS braking process. For long lasting ABS braking, e.g. from high speeds with low road friction coefficients or with strongly varying coefficients of friction, the storage chambers can be completely filled. In addition, the brake pedal travel can greatly prolong unusually. In addition to the loss of pedal comfort so that no further pressure reduction from the wheel brakes more possible and the wheels can block.

Disclosure of the invention The braking system according to the invention with the features of independent claim 1 has the advantage that during a first mode, preferably a break-by-wire mode, an electromechanical brake booster controlled by an evaluation and control unit acts on a piston of a master cylinder, while a Brake pedal is mechanically decoupled from the piston of the master cylinder. The evaluation and control unit performs a brake pressure control function and / or a brake slip control function for at least one wheel brake via the master brake cylinder acted upon by the brake booster with an increased pedal force and a downstream pumpless fluid control block. The brake system according to the invention advantageously makes it possible for a brake pressure to be built up and released depending on the driver's operation in the at least one wheel brake. As a result, various comfort and safety functions can be implemented, such as, for example, a brake assistance function, an adaptive cruise control (ACC) function, ie an adaptive cruise control function, a soft-stop function, ie a reduction of the braking pressure during the transition to standstill. a hill-hold function, ie the vehicle is automatically held in its current position at standstill on a mountain, a driver independent emergency brake function, etc. Furthermore, in case of failure of the brake booster or in case of power failure, a connection between the piston of the master cylinder and the brake pedal are made so that it is possible for the driver in an emergency to operate the brake system directly by muscle power. By decoupling the brake pedal, there are no disturbing effects on the brake pedal during the first operating mode, so that the pedal comfort is advantageously increased. In addition, the decoupling of the brake pedal in combination with the pump-less fluid control block advantageously allows existing in the fluid control block storage chambers during a brake pressure control operation and / or a brake slip control process can be emptied by a short braking pressure reduction in the master cylinder to a blockage of the wheels and thus the Ineffectiveness to prevent an anti-lock function. In addition, the use of the pumpless fluid control block eliminates the pump noise occurring in the prior art in a fluid control block with return pump. The measures and refinements recited in the dependent claims advantageous improvements of the independent claim brake system are possible.

It is particularly advantageous that the brake pedal is connected to a pedal simulator and a coupling rod whose end face is mechanically decoupled from a stop during the first mode by a predetermined distance. During the first mode of operation, the pedal simulator detects a deceleration request on the brake pedal and determines a corresponding pedal force and forwards the detection and / or determination result to the evaluation and control unit, which activates the electromechanical brake booster to generate the correspondingly enhanced pedal force, the pedal simulator generates a corresponding haptic feedback and outputs to the brake pedal. During a second operating mode, preferably an emergency mode, the coupling rod overcomes the predetermined distance, so that the end face of the coupling rod abuts the stop to transmit the pedal force generated on the brake pedal to the piston of the master cylinder, so that it is possible for the driver, the brake system directly to operate by muscle power. During the second mode, the pedal simulator is disabled and / or bypassed.

In an embodiment of the brake system according to the invention, the fluid control block for guiding a brake fluid comprises at least one inlet valve with a check valve, at least one outlet valve and at least one fluid storage chamber. In the first operating mode, the evaluation and control unit builds the

Brake pressure during a brake pressure control operation and / or a brake slip control process by a corresponding control of the Fluidsteu- block and the electromechanical brake booster short-term, so that during the brake pressure control process and / or Bremsschleupfre- gelvorgangs with brake fluid that flows back from the wheel brakes filled at least a fluid storage chamber can be emptied into the master cylinder. This makes it possible in an advantageous manner that an anti-lock function of the wheel brakes can be maintained even during a long-lasting braking operation, for example during braking operations from high speeds and at low road friction values or during braking operations with strongly changing braking conditions. variable coefficients of friction. During braking pressure reduction, the predetermined distance between the coupled with the brake pedal coupling rod and the stop is reduced. Therefore, the distance to the decoupling of the brake pedal is predetermined and coordinated with the emptying process of the at least one fluid storage chamber, that the brake pedal is mechanically decoupled from the piston of the master cylinder even after a draining operation of the at least one fluid storage chamber. This means that the distance to the decoupling of the brake pedal is chosen so large that the end face of the coupling rod does not abut against the stop even after the emptying of the at least one fluid storage chamber.

In an embodiment of the brake system according to the invention, the electromechanical brake booster comprises an electric motor and a transmission device which transmits the torque generated via the electric motor to the piston of the master brake cylinder. The transmission device converts a rotational movement into a translatory movement for actuating the master brake cylinder and transmits the torque generated by the electric motor to the pistons of the master brake cylinder with a predefinable transmission ratio. The transmission device is designed, for example, as a transmission, which comprises a rack with an inner stop and a pinion. The gear ratio can be specified for example on the execution of the rack and on the design of the pinion, wherein the rack is coupled to the piston of the master cylinder. During the first mode, the rack is driven by the electric motor through the pinion, and during the second mode, the rack is driven by the brake pedal via the front end of the inner stop of the rack connecting rod.

Alternatively, the transmission device can be designed as a screw drive which has a hollow shaft and a longitudinally movably guided hollow shaft

Includes stamp with an inner stop. The plunger is coupled to the piston of the master cylinder and is driven by the electric motor via the hollow shaft during the first mode. During the second operating mode, the plunger is driven by the brake pedal via the coupling rod which bears against the end stop on the inner stop of the plunger. In a further refinement of the brake system according to the invention, the master brake cylinder with the electromechanical brake booster and / or the fluid control block forms a functional structural unit, so that a compact, space-saving design is possible. That means all three

Components can be summarized in a single unit. Alternatively, the master cylinder with the electromechanical brake booster or with the fluid control block form a structural unit.

Advantageous embodiments of the invention described below are shown in the drawings.

Brief description of the drawings

1 shows a schematic block diagram of a first embodiment of a brake system according to the invention.

2 shows a schematic block diagram of a second embodiment of a brake system according to the invention.

Embodiments of the invention

In the drawings, like reference numerals designate elements and components that perform the same or analog functions.

As can be seen from FIG. 1, a first embodiment of a brake system 1 according to the invention comprises an actuator unit 10 which has a brake pedal 2, a pedal simulator 4 and an electromechanical brake booster 12, a master cylinder 20, a fluid control block 30 and a plurality of wheel brakes 42, 44, 46 , 48, which are controlled via the master cylinder 20 and the fluid control block 30 with a predetermined brake pressure. The brake pedal 2 is connected to the pedal simulator 4 and a coupling rod 3. The electromechanical brake booster 12 comprises an electric motor 13 and a transmission device 14, which generates the torque generated by the electric motor 13 or the force generated on a piston 21 of the Master brake cylinder 20 transmits. Thus, the transmission device 14 for controlling the master cylinder 20 can convert a rotational movement into a translatory movement and transmit the torque generated by the electric motor 13 with a predeterminable transmission ratio to the piston 21 of the master cylinder 20. In order to realize a corresponding transmission ratio, the transmission device can be executed in several stages. For implementing the electromechanical brake booster, a suitable electric drive can be coupled to any transmission device, such as a worm drive, a belt drive, a chain drive, etc., can be used to the piston 21 of the

Master cylinder 20 to apply a corresponding setting for a brake pressure with a force.

In the illustrated first embodiment of FIG. 1, the transmission device is designed as a transmission 14, which includes a rack 14.1 with an inner stop 5.1 and a pinion 14.2. The gear ratio can be specified by the execution of the rack 14.1 and the execution of the pinion 14.2. 1, the rack 14.1 is coupled to the piston 21 of the master cylinder 20 and is driven by the electric motor 13 via the pinion 14.2 during a first operating mode, which here corresponds to a brake-by-wire mode. During a second operating mode, which here corresponds to an emergency operating mode, the rack 14.1 is driven by the brake pedal 2 via the coupling rod 3 bearing an end face 3.1 on the inner stop 5.1 of the rack 14.1.

As can be seen from FIG. 2, a second embodiment of a brake system 1 'according to the invention, similar to the first embodiment of the brake system 1, comprises an actuator unit 10', the master brake cylinder 20, the fluid control block 30 and the wheel brakes 42, 44, 46, 48 be controlled via the master cylinder 20 and the fluid control block 30 with a predetermined brake pressure. Analogous to the actuator unit 10 of the first embodiment of the brake system 1, the actuator unit 10 'of the second embodiment of the brake system 1' comprises a brake pedal 2, a pedal simulator 4 and an electromechanical brake booster 12 ', which differs from the electromechanical brake booster 12 of the first embodiment. The brake pedal 2 is connected to the pedal simulator 4 and a coupling rod 3. Analogous to the electromechanical brake booster 12, the electromechanical brake booster 12 'likewise comprises an electric motor 13' and a transmission device 14 ', which transmits the torque or the force generated by the electric motor 13' to the piston 21 of the master brake cylinder 20.

In the illustrated second embodiment of FIG. 2, the transmission device is designed as a screw 14 ', a hollow shaft 14.2' and in the hollow shaft 14.2 'longitudinally movably guided punch 14.1' with an inner

Stop 5.1 'includes. The punch 14.1 'is coupled to the piston 21 of the master cylinder 20 and is driven during the first mode by the electric motor 13' via the hollow shaft 14.2 'of the screw 14'. During the second mode of operation, the plunger 14.1 'from the brake pedal 2 via the with the front side 3.1 on the inner stop 5.1' of the punch 14.1 'fitting

Coupling rod 3 driven.

As further shown in FIGS. 1 and 2, the master cylinder 20, which is exemplified as a tandem master cylinder, fertilize via corresponding Fluidverbin- with a fluid reservoir 22, which is used as a reservoir for the brake fluid, and the downstream pumpless fluid block 30. The pumpless fluid block 30 comprises for each of the illustrated wheel brakes 42, 44, 46, 48 an inlet valve 32.1, 34.1, 36.1, 38.1 and an outlet valve 32.2, 34.2, 36.2, 38.2, wherein for each inlet valve 32.1, 34.1, 36.1, 38.1 a check valve 32.3, 34.3, 36.3, 38.3 is connected in parallel. The respective parallel-connected check valve 32.3, 34.3, 36.3 or 38.3 allows pressure equalization when the associated inlet valve 32.1, 34.1, 36.1 or 38.1 is closed. In addition, the check valves 32.3, 34.3, 36.3, 38.3 may each have a throttle in order to perform the pressure equalization in a closed associated intake valve 32.1, 34.1, 36.1, 38.1 not abruptly but with a predetermined compensation behavior.

A first inlet valve 32.1 with a first check valve 32.3 and a first outlet valve 32.2 are associated, for example, with a first wheel brake 42, and a second inlet valve 34.1 with a second check valve 34.3 and a second exhaust valve 34.2 are associated with a second wheel brake 42, wherein the first and second inlet valves 32.1, 34.1 and the first and second exhaust valves 32.2, 34.2 are connected via a common fluid connection with a first chamber of the master cylinder 20 and form a first brake circuit , wherein the inlet valves 32.1, 34.1 are decoupled via a check valve 31 from the exhaust valves 32.2, 34.2. A third intake valve 36.1 with a third check valve 36.3 and a third exhaust valve 36.2 are associated with a third wheel brake 46, and a fourth intake valve 38.1 with a fourth check valve 38.3 and a fourth exhaust valve 38.2 are associated with a fourth wheel brake 48, the third and fourth intake valves 36.1 , 38.1 and the third and fourth outlet valves 36.2, 38.2 are connected via a common fluid connection with a second chamber of the master cylinder 20 and form a second brake circuit, the inlet valves 36.1, 38.1 being decoupled via a check valve 37 from the outlet valves 36.2, 38.2. The intake valves 32.1, 34.1, 36.1, 38.1 are connected on the input side to the master brake cylinder 20 and on the output side each to one of the wheel brakes 42, 44, 46, 48. The exhaust valves 32.2, 34.2, 36.2, 38.2 are on the input side each connected to one of the wheel brake 42, 44, 46, 48 and the output side to the master cylinder 20. In addition, in each case two of the outlet valves 32.2, 34.2, and 36.2, 38.2 are connected on the output side to a fluid storage chamber 33 or 39.

The operation of the embodiment according to the invention will be described below with reference to FIGS. 1 and 2.

In a fault-free operation, the brake system is operated as a brake-by-wire system, i. the pedal force generated by the muscle power of the driver is not transmitted to the brake torque generating element, here on the master cylinder 20, but the evaluation and control unit 11, 11 'generates the required braking force by means of the electromechanical brake booster

12, 12 '. Therefore, various comfort and safety functions can be implemented, such as a brake assist function, an ACC function, a soft-stop function, a hill-hold function, a driver-independent emergency brake function, etc. During the first operating mode, the brake pedal 2 is mechanically decoupled from the piston 21 of the master cylinder 20, ie the front side 3.1 of the coupling rod 3 has a predeterminable distance 5, 5 'to the inner stop 5.1 of the rack 14.1 or to the inner stop 5.1' of the punch 14.1 ' on. During the first mode of operation, the pedal simulator 4 detects a deceleration request on the brake pedal 2 and determines a corresponding pedal force and forwards the detection and / or determination result to the evaluation and control unit 11 or 11 ', which the electromechanical brake booster 12 and 12' to Generation of the correspondingly enhanced pedal force controls. In addition, the pedal simulator 4 generates a corresponding pedal reaction or haptic feedback and outputs it to the brake pedal 2.

Detects the pedal simulator 4 or a corresponding sensor unit, not shown, a deceleration request, then the pedal force generated by the driver is determined and the electromechanical brake booster 12 or 12 'is driven by the evaluation and control unit 11, 11' to generate the increased pedal force accordingly. In addition, the brake pressure generated in the master cylinder 20, which is detected by the evaluation and control unit 11, 11 ', for example, with a sensor unit, not shown, via the normally open inlet valves 32.1, 34.1, 36.1 and 38.1 to the corresponding wheel brakes 42, 44, 46th and 48 forwarded. If the evaluation and control unit 11 or 11 'during a braking operation, a tendency to lock one of the wheels, then the corresponding inlet valve 32.1, 34.1, 36.1 or 38.1 closed to another pressure build-up in the corresponding wheel 42, 44, 46 and 48 to prevent. The blocking tendency can be determined by the evaluation and control unit via corresponding sensors, not shown. If this measure is not sufficient to cancel the blocking tendency, the associated normally closed exhaust valve 32.2, 34.2, 36.2 or 38.2 is opened until the wheel slip decreases again, then the exhaust valve 32.2, 34.2, 36.2 and 38.2 closed again , That by the

Opening of the exhaust valve 32.2, 34.2, 36.2 and 38.2 from the associated wheel brake 42, 44, 46 and 48 flowing brake fluid is received by the associated fluid storage chamber 33, 39. After reaching a stable wheel speed, the associated intake valves 32.1, 34.1, 36.1 and 38.1 are opened again. The process described is repeated until is stopped by a detected driver's request, the braking process, or the vehicle has come to a standstill. After release of the brake pedal 2 by the driver, the brake fluid received by the fluid storage chamber 33 or 39 flows back through storage chamber spring via corresponding check valves 31 and 37 into the master cylinder 20. That's it

System ready for a new braking with an anti-lock function. In a long-lasting braking operation with an anti-lock function, e.g. During a braking process from a high speed at a low Fahrreibreibwert or when the coefficients of friction change significantly during the braking process, the fluid storage chambers 33, 39 can be completely filled with brake fluid.

Detects the evaluation and control unit 11, 11 ', for example by means of a sensor unit, not shown, and / or by evaluating the duration of the associated braking operation and / or the number and / or duration of the driving operations of the exhaust valves 32.2, 34.2, 36.2 and 38.2, to reduce the pressure in the associated wheel brake 42, 44, 46 and 48 and to direct the brake fluid into the associated fluid storage chamber 33 and 39, that the associated fluid storage chamber 33 and 39 is filled, then the evaluation and control unit 11 and 11 ', the corresponding intake valves 32.1, 34.1 or

36.1, 38.1 and switches off the electromechanical brake booster 12, 12 'short term, so that the prevailing brake pressure during the associated brake pressure control operation and / or brake slip control process is temporarily reduced by the fact that the piston 21 of the master cylinder 20, the rack 14.1 with the inner stop 5.1 or the punch 14.1 'with the inner stop 5.1 in the direction of the end face 3.1 of the coupling rod 3 is moved, whereby the distance 5 or 5' between the end face 3.1 of the coupling rod 3 and the inner stop 5.1 or 5.1 'is at least partially overcome. The distance 5 or 5 'for decoupling the brake pedal 2 is predetermined and matched with the emptying process of the fluid storage chambers 33 and 39, respectively, that the brake pedal 2 is decoupled mechanically from the piston 21 of the master cylinder 20 even after an emptying operation of the fluid storage chambers 33 and 39 respectively , This means that the evaluation and control unit 11 or 11 'interrupts the brake pressure control process and / or the brake slip control process for a short time and can be interrupted by the dismantling of the brake control system. pressure the fluid storage chambers 33 and 39 in the master cylinder 20 and emptied into the surge tank 22. Subsequently, the evaluation and control unit 11 or 11 'controls the electromechanical brake booster 12 or 12' again and continues the brake pressure control operation and / or the brake slip control operation.

In case of failure of the first mode, i. the brake-by-wire mode, a mechanical connection between the brake pedal 2 and the piston 21 of the master cylinder 20 is made by the pedal simulator 4 is switched off or bridged. By switching off or bridging the

Pedal simulator 4 will be a second mode, i. an emergency mode activated during which the coupling rod 3 the predetermined distance 5 or 5 'overcomes, so that the front side 3.1 of the coupling rod 3 on the inner stop 5 of the rack 14.1 and the inner stop 5' of the punch 14.1 'is applied. Thereby, the pedal force generated by muscle power on the brake pedal 2 is transmitted to the piston 21 of the master cylinder 20, so that it is possible for the driver to operate the brake system without the assistance of the electromechanical brake booster 12 or 12 '.

The brake system 1 or 1 'according to the invention can be actuated via a compact electromechanical actuator unit 10, 10' with a pedal simulator 4 which can build up and reduce a brake pressure independently of the driver actuation in the master brake cylinder 20, so that braking processes in hybrid vehicles Cooperation with an electric motor in the generator mode are possible, so that the reaction to the brake pedal 2 corresponds to the vehicle deceleration. The master cylinder 20 can form a functional unit with the electromechanical brake booster 12, 12 'and / or the fluid control block 30. In addition, the brake system according to the invention 1 or 1 'in combination with the pumpless fluid block 30 Bremsdruckregel- operations and / or brake slip control operations perform, with the mechanical decoupling of the brake pedal 2 from the master cylinder 20 during the first mode in an advantageous manner no disturbing effects on the brake pedal 2 can occur. The pumpless fluid control block 30 also eliminates the pump noises which occur in conventional fluid control blocks which actuate a fluid pump in the brake pressure control process. and / or brake slip control operations. In addition, the brake system according to the invention, by virtue of the short brake pressure reduction in the master brake cylinder during a brake pressure control operation and / or a brake slip control operation, permits a permanent mode of operation of the anti-lock function during the brake pressure control operation and / or brake slip control operation.

.oOo.

Claims

claims A brake system comprising an actuator unit (10, 10 ') comprising a brake pedal (2), a pedal simulator (4) and an electromechanical brake booster (12, 12'), and a master cylinder (20) via which at least one wheel brake brake (42, 44, 46, 48) is drivable with a predeterminable brake pressure, wherein the brake pedal (2) or the electromechanical brake booster (12, 12 ') for establishing or reducing a brake pressure on the master cylinder (20) act, characterized in that during a first operating mode, preferably a break-by-wire operating mode, the electromechanical brake booster (12, 12 ') acts on a piston (21) of the master brake cylinder (20) under the control of an evaluation and control unit (11, 11') , while the brake pedal (2), mechanically decoupled from the piston (21) of the master cylinder, wherein the evaluation and control unit (11, 11 ') via the brake booster (12, 12') acted upon by an increased pedal force Ha Uptbremszylinder (20) and a downstream pumpless fluid control block (30) performs a brake pressure control function and / or a brake slip control function for the at least one wheel brake (42, 44, 46, 48). 2. Brake system according to claim 1, characterized in that the brake pedal (2) with the pedal simulator (11, 11 ') and a coupling rod (3) is connected, the end face (3.1) during the first mode by a predetermined distance (5, 5 ') is mechanically decoupled from a stop (5.1, 5.1'), wherein the pedal simulator (4) during the first mode detects a deceleration request on the brake pedal (2) and determines a corresponding pedal force and the detection and / or determination result to the evaluation and control unit (11, 11 '), which drives the electromechanical brake booster (12, 12') to produce the correspondingly increased pedal force, and wherein the pedal simulator (4) generates a corresponding haptic feedback and outputs to the brake pedal (2). 3. Brake system according to claim 1 or 2, characterized in that the coupling rod (3) during a second mode, preferably an emergency mode, the predetermined distance (5, 5 ') overcomes, so that the end face (3.1) of the coupling rod (3). abuts against the stop (5, 5 ') in order to transmit the pedal force generated on the brake pedal (2) to the piston (21) of the master brake cylinder (20), the pedal simulator (4) being deactivated and / or bridged during the second operating mode is. 4. Brake system according to one of claims 1 to 3, characterized in that the fluid control block (30) at least one inlet valve (32.1, 34.1, 36.1, 38.1), at least one outlet valve (32.2, 34.2, 36.2, 38.2) and at least one FIu- The evaluation and control unit (11, 11 ') controls the brake pressure during a brake pressure control process and / or a brake slip control operation by a corresponding control of the electromechanical brake booster (12, 11, 11). 12 ') and / or the fluid block (30) degrades briefly, so that during the brake pressure control operation and / or the brake slip control process with Bremsflu- id, which flows back from the wheel brakes (42, 44, 46, 48) filled at least one fluid storage chamber ( 33, 39) in the master cylinder (20) can be emptied. 5. Brake system according to claim 4, characterized in that the distance (5, 5 ') for decoupling the brake pedal (2) is predetermined and matched with the emptying process of the at least one fluid storage chamber (33, 39) that the brake pedal (2) Even after a draining operation of the at least one fluid storage chamber (33, 39) is mechanically decoupled from the piston (21) of the master cylinder (20). 6. Braking system according to one of claims 1 to 5, characterized in that the electromechanical brake booster (12, 12 ') comprises an electric motor (13, 13') and a transmission device (14, 14 '), which by the electric motor (13, 13 ') transmits generated force to the piston (21) of the master cylinder (20). 7. Brake system according to claim 6, characterized in that the transmission device (14, 14 ') for controlling the master brake cylinder (20) has a rotating converts movement in a translational movement and transmits the torque generated by the electric motor (13, 13 ') with a predetermined ratio on the piston (21) of the master cylinder (20). 8. Brake system according to claim 6 or 7, characterized in that the transmission device is designed as a transmission (14) comprising a rack (14.1) with an inner stop (5.1) and a pinion (14.2), wherein the gear ratio on the execution the rack (14.1) and the design of the pinion (14.2) can be predetermined, wherein the rack (14.1) is coupled to the piston (21) of the master cylinder (20), and wherein the rack (14.1) during the first mode of operation of the electric motor (13) via the pinion (14.2) is driven and during the second mode of the brake pedal (2) via the front side (3.1) on the inner stop (5.1) of the rack (14.1) adjacent the coupling rod (3) is driven. 9. Braking system according to claim 6 or 7, characterized in that the transmission device is designed as a screw (14 ') having a hollow shaft (14.2') and in the hollow shaft (14.2 ') longitudinally movably guided punch (14.1') with an inner Stop (5.1 '), wherein the punch (14.1') is coupled to the piston (21) of the master cylinder (20), and wherein the punch (14.1 ') during the first mode by the electric motor (13') via the hollow shaft (14.2 ') is driven and during the second mode of the brake pedal (2) via the front side (3.1) on the inner stop (5.1') of the punch (14.1 ') adjacent coupling rod (3) is driven. 10. Brake system according to one of claims 1 to 8, characterized in that the master brake cylinder (20) with the electromechanical brake booster (12, 12 ') and / or the fluid control block (30) forms a functional unit. .o0o.