EP3487734A1 - Brake system and method for the operation thereof - Google Patents

Abstract

The invention relates to a brake system for motor vehicles comprising: a main brake cylinder (10) having at least one first and one second main brake cylinder piston (8, 9), which are arranged behind one another and delimit a first and a second pressure chamber (6, 7), to which a respective brake circuit (I, II) with wheel brakes (1, 2; 3, 4) is connected, wherein the first main brake cylinder piston (8) is connected to a brake pedal (13) via an actuation-force-transmitting pressure bar (12); a pressure medium storage container (5) associated with the pressure chambers (6, 7) and under atmospheric pressure; an electrically controllable pressure source (50a, 50b) for each brake circuit (I, II), having a suction connection (41) and a pressure connection (42), wherein the pressure connection (42) is connected to the wheel brakes of the brake circuit and wherein the suction connection (41) is connected to the main brake cylinder (10) via a second, in particular currentlessly closed valve (14a, 14b); and a third, in particular currentlessly open valve (18a, 18b) for each brake circuit (I, II), via which the main brake cylinder (10) is connected to the wheel brakes of the brake circuit, wherein, in each brake circuit (I, II), the suction connection (41) of the pressure source (50a, 50b) is connected to the pressure medium storage container (5) via a first valve (15a, 15b). The invention also relates to a method for operating a brake system of this type.

Description

Brake system and method for its operation

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

From US 2015/0061366 AI a brake system without vacuum brake booster known with a tandem master cylinder ^¬ at the two pressure chambers each a brake circuit is connected with wheel brakes, wherein the first master cylinder piston is directly connected to a brake pedal, and a pressure medium reservoir , Each brake circuit is an electrically controllable pump whose pressure port is connected via an inlet valve per wheel brake with the wheel brakes of the brake circuit and the suction port is connected via a normally closed suction valve with the corresponding pressure chamber, and a normally closed isolation valve, via which the corresponding pressure chamber of the master cylinder with the wheel brakes of the

Brake circuit is connected, available. The brake system comprises an additional electrically controllable pressure source in the form of a motor-driven, dual-circuit cylinder device, whose two pressure chambers are each connected to one of the brake circuits. Due to the additional electrically controllable pressure source, the known brake system is relatively expensive and large.

It is an object of the present invention to provide a brake system which requires no negative pressure and yet is inexpensive, compact and lightweight. The brake system should also be suitable for recuperative braking, various assistance functions and autonomous driving. It is another object of the invention to provide a method for operating the brake system. The object is achieved by a brake system according to claim 1 and a method for operation according to claim 6. The invention is based on the idea that each brake circuit of the suction port of the pressure source is additionally connected via a (first) valve with the pressure medium reservoir. Thus, if necessary, in addition to or as an alternative to pressure medium from the master cylinder, the pressure source can suck in pressure medium volume from the pressure medium reservoir.

The brake system according to the invention therefore represents a combined power-assisted and foreign-power brake system. During braking, it is possible to switch between the auxiliary-power operating mode and the foreign-power operating mode.

The first master cylinder piston is connected to a brake pedal (directly) via an actuating force transmitting push rod, i. there is no brake booster between brake pedal and main brake cylinder, e.g. Vacuum brake booster, switched.

The first valve is preferably designed to be normally closed in order to use proven, cost-effective series (valve) technology and to be able to better control the volume flows in the brake system during actuation. This ensures that the proportion of volume which is introduced into the wheel brakes by the driver via the master brake cylinder and the volume fraction which the pressure source draws directly from the pressure medium reservoir are determined or determined more precisely. (e.g., from a model calculation).

Under a brake pedal operation size is understood according to the invention a physical quantity which is characteristic of the degree of movement of the brake pedal when actuated by the driver. A pressure generated in the master cylinder is (according to the nomenclature of this application) not a brake pedal operating variable in this sense. A brake pedal operating amount is, for example, a brake pedal angle, a brake pedal travel, or a position or a travel of the first master cylinder piston.

In the brake system according to the invention, both a brake pedal ^{actuating variable} and a pressure generated in the main brake cylinder by the applied foot force are preferably determined or measured. The variables mentioned together characterize the deceleration request of the driver.

Preferably, the third valves, via which the main ^¬ brake cylinder is connected to the wheel brakes, running normally open, for example, to allow the driver in a power failure of the brake system, a hydraulic penetration of the wheel brakes.

Preferably, a low-pressure accumulator is provided per brake circuit, wherein the suction port of the pressure source is connected to the low-pressure ^¬ memory. The low-pressure accumulator is used, for example, to receive pressure medium from the wheel brakes, for example when the brake pressure is reduced via one of the exhaust valves.

Preferably, an exhaust valve is provided for each wheel brake, via which the wheel brake is connected to the corresponding low-pressure accumulator.

Furthermore, an intake valve is preferably provided for each wheel brake, which is arranged between the corresponding third valve and the wheel brake.

According to a development of the invention is in the second Master brake cylinder piston integrated a brake pedal feel simulator, which comprises a guided in the second master cylinder piston simulator piston, which is supported via an elastic element on the second master cylinder piston. The brake pedal feel simulator allows a brake pedal stroke in operating situations in which the brake pedal is actuated and the suction sides of the pressure sources are not connected to the master cylinder but to the pressure medium reservoir.

The brake pedal feel simulator is preferably designed such that the simulator piston is only movable upon actuation of the brake pedal when the second pressure chamber is hydraulically shut off. The brake pedal feel simulator thus enables a brake pedal stroke even when the master cylinder pressure chambers, e.g. by means of the first and third valves, hydraulically separated from the wheel brakes and the suction sides.

The brake system preferably comprises no further electrically controllable pressure source.

Preferably, a pressure measuring device for detecting a pressure of the master cylinder and a Po ^¬ sitionsmessvorrichtung for detecting a brake pedal operation amount are provided in the brake system.

The pressure measuring device particularly preferably detects the pressure in the second pressure chamber of the master brake cylinder.

The position measuring device particularly preferably detects a displacement of the first master cylinder piston.

The invention also relates to a method for operating a brake system according to the invention. In order to build up brake pressure at the wheel brakes, the first valves are or are opened in a second brake actuation phase, and the pressure sources are activated. Particularly preferred are or are the second valves closed. This will be in the second brake actuation phase

Pressure medium conveyed by means of the pressure sources from the pressure medium reservoir via the first valves in the wheel brakes.

Preferably, the second brake actuation phase is performed when, due to an actuation of the brake pedal by the driver, a predetermined, second pressure value in the master cylinder is achieved. Particularly preferably, the second brake ^lining tätigungsphase performed when the second pressure value is reached in the second pressure chamber of the master cylinder.

Preferably, the second brake actuation phase is performed additionally or alternatively, when a brake pedal actuation variable reaches a predetermined, second value due to actuation of the brake pedal by the driver. Particularly preferably, the second brake actuation phase is carried out when the displacement of the first master cylinder piston reaches a ^{predetermined} limit value.

A predetermined second pressure value, value or limit value is understood to be a pressure value, value or limit value which is predetermined or defined (for example stored in an electronic control unit of the brake system) or which is determined as a function of the situation (eg in an electronic control unit) Control unit, eg based on sensor data, driving dynamics conditions, etc.).

Preferably, a second desired output pressure of the pressure source based on a measured pressure of the master cylinder and a second predetermined functional relationship is determined and during the second brake actuation phase, the output pressure of the pressure source is set to the specific second target output pressure. If the brake system does not have a brake pedal ^feeler simulator, the determination of the second

Target output pressure preferably no brake actuation amount considered. If the brake system has an integrated brake pedal feel simulator, then the second

Target output pressure of the pressure source is preferably determined based on a measured pressure of the master cylinder, a Bremsbetä- sion size and a second predetermined functional relationship.

The second brake actuation phase is performed alternatively or additionally when braking is requested by an autopilot function. The second brake actuation phase is also performed when there is no actuation of the brake pedal by the driver.

Are preferred or are to build up brake pressure at the wheel brakes on actuation of the brake pedal by a

Driver connected in a first brake actuation phase, the suction ports of the pressure sources by means of the second valves to the master cylinder and the pressure sources are driven. Thus, pressure medium is conveyed by means of the pressure sources from the master cylinder via the second valves in the wheel brakes.

During the first brake actuation phase, the third valves are preferably closed, so that pressure medium is not conveyed in a circle.

A first desired output pressure of the pressure source is preferably determined on the basis of a measured pressure of the master brake cylinder, a measured brake pedal actuation variable and a first given functional relationship determined and during the first brake actuation phase, the pressure sources are driven so that the output pressure of the pressure sources is set to the determined first target output pressure.

Preferably, the first brake actuation phase is performed when, due to the actuation of the brake pedal by the driver, a first predetermined pressure value in the master cylinder is achieved. Particularly preferably, the first brake actuation phase is performed when a first predetermined pressure value in the second pressure chamber of the master cylinder is reached.

Preferably, the first brake actuation phase is performed alternatively or additionally, when due to the actuation of the brake pedal by the driver, a brake pedal operation amount reaches a first predetermined value. Particularly preferably, the first brake actuation phase is performed when the displacement of the first master cylinder piston reaches a first predetermined limit.

In this case, the first pressure value for initiating the first brake actuation phase is preferably smaller than the second pressure value for initiating the second brake actuation phase or the first predefined value / limit value is smaller than the second predefined value / limit value.

Are preferred or are at the beginning of the operation of the

Brake pedal in a pre-phase, the second and third valves open and the pressure sources are not activated. Thus, pressure medium is displaced by the driver of the master cylinder in the wheel brakes and to the suction side of the pressure sources. Particularly preferably, the measured pressure of the master cylinder is the measured pressure of the second

Pressure chamber of the master cylinder.

Particularly preferably, the measured

Brake pedal operation amount by a measured displacement of the first master cylinder piston.

The brake system according to the invention and the method according to the invention for operating the brake system also offer the advantage of a known brake pedal feeling for the driver.

Further preferred embodiments of the invention will become apparent from the claims and the following description with reference to figures.

They show schematically:

Fig. 1 shows a first exemplary brake system, and

Fig. 2 shows the integrated brake pedal feel simulator

 Brake systems from Fig. 1 in detail view.

In Fig. 1, a first exemplary brake system of a motor vehicle is shown schematically.

The brake system comprises a brake pedal actuated main ^¬ brake cylinder 10 with two pressure chambers 6, 7, wherein each pressure chamber 6 or 7, a brake circuit I or II with two wheel brakes 1, 2 or 3, 4 is assigned, and a master cylinder associated with atmospheric pressure standing pressure medium reservoir 5. The dual-circuit master cylinder 10 comprises two pistons 8, 9 arranged one behind the other, which delimit the two hydraulic pressure chambers 6, 7 in a housing. Brake pedal 13 is mechanically coupled directly to a push rod (piston rod) 12, which is mechanically coupled or connected directly to the first piston 8, ie, the first piston 8 is on the actuating forces transmitting push rod 12 directly to the

Brake pedal 13 connected and is operated directly by the driver, without the interposition of a brake booster.

The pressure chambers 6, 7 unspecified Druckaus ^¬ same lines are assigned to the pressure medium reservoir 5, the hydraulic connection is separated at a displacement of the piston 8, 9.

The brake system further includes, for example, a hydraulic control unit HCU, which corresponds to a modified ESC structure (ESC: Electronic Stability Control). The hydraulic control unit HCU is preferably associated with an electronic control unit (not shown) ECU.

The hydraulic control and regulating unit comprises a two-circuit motor-pump unit with two pumps 50a, 50b, which are jointly driven by an electric motor 51, in particular brushless motor, and each brake circuit I, II a low-pressure accumulator 17a and 17b and two electrically controllable valves 18a, 14a and 18b, 14b. For each wheel brake 1-4, an intake valve 21 and an exhaust valve 19 are provided for setting wheel-specific brake pressures for the wheel brakes.

Via the, advantageously normally open, valve 18a or 18b (third valve) is the master cylinder pressure chamber 8 and 9 respectively connected to the wheel brakes 1, 2 and 3, 4 of the corresponding brake circuit I and II.

Intake valve 21 is each arranged between the master cylinder 10, in particular the valve 18a or 18b, and the wheel brake 1-4. That the input ports of the intake valves 21 are connected to the brake master cylinder 10 by means of a brake circuit (I, II) by means of a line in which the valve 18a or 18b is arranged. Via the exhaust valve 19, the wheel brake 1-4 is connectable to the corresponding low pressure accumulator 17a or 17b for discharging pressure medium, e.g. for a reduction of wheel brake pressure. That the output ports of the exhaust valves 19 are connected in a brake circuit to the low-pressure hydraulic accumulator 17a or 17b.

Each pump 50a, 50b comprises a suction port 41 and a pressure port 42, wherein the pressure port 42 is connected to the wheel brakes 1, 2 or 3, 4 of the corresponding brake circuit I or II and wherein the suction port 41 via the, preferably normally closed, (second) valve 14a, 14b is connected to the ent ^¬ speaking pressure space 8 and 9 of the master cylinder 10 degrees.

Each low-pressure accumulator 17a, 17b is connected to the suction side 41 of the corresponding pressure source, for example via a non-return valve 16a, 16b closing in the direction of the low-pressure accumulator. Pump 50a, 50b, connected.

In addition to the known ESC module structure 20, a hydraulic connection 31a, 31b is provided per brake circuit I, II from the suction side 41 of the pump 50a, 50b to the pressure medium reservoir 5, in which a, advantageously normally closed, Zuschaltventil (first valve ) 15a, 15b is orders. The hydraulic connections 31a, 31b are independent of the position of the master brake cylinder pistons 8, 9.

The pressure ports 42 of the pressure sources 50a, 50b are each connected via a hydraulic (unspecified) Pulsationsdämp- tion element to the connecting line between the third valve 18a, 18b and associated inlet valves 21.

For example, to detect a master cylinder pressure, the brake system comprises a pressure measuring device 45, e.g. a redundant pressure sensor, for detecting the pressure in the second pressure chamber 7 of the master cylinder 10th

Furthermore, the brake system comprises a position measuring device 46 for detecting a brake pedal operating variable. Preferably, a displacement of the first master cylinder piston 8 is detected as a brake pedal operation amount.

The exemplary brake system comprises a brake pedal feel simulator 60. For this purpose, the second master brake cylinder piston 9 is provided with an integrated simulator piston 61. Details of the brake pedal feeling simulator 60 will be explained in more detail together with ^¬ menhang FIG. 2. Fig. 2 shows the integrated into the master cylinder 10

Brake pedal feel simulator 60 of the brake systems of Fig. 1 in detail view. The brake pedal feeling simulator 60 is integrated with the second master cylinder piston 9. Brake pedal feel simulator 60 includes a simulator piston 61 guided in the second master brake cylinder piston 9 which extends over an elastic member 62, e.g. a simulator spring, is supported on the second master cylinder piston 9.

On the master cylinder 10, a first terminal 72 to Connection of the first pressure chamber 6 with the brake circuit I seen ^¬ before, according to a second port 73 is provided for connecting the second pressure chamber 7 to the brake circuit II. About the pressure medium reservoir connections 74 of the master cylinder 10 is connected to the pressure fluid reservoir 5.

An elastomer stop 63, which comes into contact with sufficient displacement of the simulator piston 61 on the master brake cylinder piston 9, is fastened to the simulator piston 61 in the region facing away from the brake pedal.

Between master brake cylinder piston 9 and simulator piston 61, a simulator seal 64 is arranged, which is the first

Pressure chamber 6 of the master cylinder 10 of a through the

Master cylinder piston 9 and the simulator piston 61 limited simulator space 65 seals. In master brake cylinder piston 9, a passage 66 is provided, via which the simulator space 65 is connected to the pressure medium reservoir port 74.

Master brake cylinder piston 8 is supported on the simulator piston 61 via a first spring 70, which is arranged in the first pressure chamber 6 and is advantageously preloaded. Between master brake cylinder piston 8 and simulator piston 61, a tether sleeve and a tether screw 71 are arranged.

In the second pressure chamber 7 of the master cylinder 10, an unspecified second spring for returning the second piston 9 is arranged, which is supported on the housing of the master cylinder 10.

According to the example, the position measuring device 46 comprises a piston 8 arranged on the magnetic ring 48, the displacement of a in the master cylinder housing arranged displacement sensor element 49 is detected.

Upon actuation of the brake pedal 13, the piston 8 and the first spring 70 of the piston 9 including simulator piston 61 is displaced, as long as pressure medium from the pressure chambers 6, 7 can escape. Is by a closing of the valves 14a, 14b (with the valves 18a, 18b closed) of the pressure chambers 7 abge ^¬ blocks, so the piston 9 can not be moved. However, a further displacement of the piston 8 (and thus a further pedal stroke) is still possible due to a displacement of the simula ^¬ torkolbens 61 in the fixed piston 9.

The integrated brake pedal feeler simulator 60 is thus designed such that it can only be moved when the valves 14a, 14b are closed.

According to the example, the brake system of FIG. 1 is operated with a normal braking initiated by the driver (with amplification) as follows:

The driver actuates the brake pedal 13 and displaces the piston rod 12 directly with the first piston 8 of the

Master cylinder 10 is coupled. This movement is detected by means of the position measuring device 46.

In a so-called preliminary phase (filling phase) at the beginning of the

Brake operation, the driver via the open or opened third valves 18a, 18b (as well as open or open intake valves 21) connected directly to the wheel 1-4 and can apply the brake pads or pre-fill the wheel 1-4. At the same time, the second valves 14a, 14b are opened. Thus, the master cylinder 10 and the electrically controllable pressure source 50a, 50b prefilled. After this, for example, pre-defined by trials, the third valves 18a, 18b are closed. In the following first brake actuation phase, the direct hydraulic connection between the master cylinder 10 (driver) and wheel brakes 1-4 is interrupted (third valves 18a, 18b closed), but the second valves 14a, 14b remain open, so that the driver continues to the suction side 41st the pressure source 50a, 50b occurs. The pressure sources 50a, 50b are driven to promote a higher brake pressure to the wheel brakes 1-4. The target brake pressure to be generated by the pressure sources 50a, 50b is determined from a predetermined (first) relationship between brake pedal operation amount (eg, pedal travel or travel of the piston 8, by position measuring device 46) and pressure at the pressure measurement device 45.

By gently starting up the pressure sources 50a, 50b, the driver only has to "track" the foot to provide the volume required for the pressure buildup, so that a "springer behavior" known from the vacuum booster can be represented.

By way of example, the pre-phase ends or the first brake-actuation phase begins when, due to the actuation of the

Brake pedal a first predetermined pressure value in the second pressure chamber 7 of the master cylinder 10 (eg 1 bar) is reached or the brake pedal actuation size reaches a first predetermined value, for example, the displacement of the first master brake ^¬ cylinder ^piston 8 reaches a first predetermined limit. At a predetermined or situation-dependent determined second limit for the brake pedal actuation quantity (eg the pedal travel or the displacement of the piston 8) or at a predetermined or situation-dependent determined second pressure value for the master brake cylinder pressure (pressure measuring device 45) and the second valves 14a, 14b are closed. Simultaneously with the closing of the valves 14a, 14b, the container connections 31a, 31b are opened to the pressure sources 50a, 50b (by opening the first valves 15a, 15b) to provide a pressure medium volume for further pressurization. This corresponds to a second brake actuation phase or initiates a second brake actuation phase.

In the second brake actuation phase, the pressure sources 50a, 50b are activated in such a way that a second desired output pressure is set. The second target output pressure is determined based on the measured master cylinder pressure, for example, the pressure of the second master cylinder pressure chamber, and a second predetermined functional relationship. By way of example, the second desired output pressure is determined predominantly via the pressure sensor 45 and then the output pressure of the pumps 50a, 50b is set, eg no brake actuation variable is taken into account if the brake system does not comprise a brake pedal ^sensation simulator.

If the piston 9 is provided with an integrated brake pedal feeler simulator 60 that can be designed to move only upon reaching the closing of the valves 14a, 14b, this allows the driver another pedal stroke. So stand for the detection of the driver's request in this second as well

Brake actuation phase two physically redundant signals (master cylinder pressure and brake pedal actuation size). Then, the second target output pressure based on the measured master cylinder pressure, for example according to the pressure of the second master cylinder pressure space, and the measured brake operation amount.

For driving the pumps 50a, 50b, a well controllable electric motor 51 is preferably provided.

When releasing the brake by the driver, an advantageous switching order of the valves is selected in the starting position. A vehicle dynamics control can with the erfindungsgem

 Brake system be carried out in the usual way.

The brake system according to the invention allows an externally controllable and / or assistance functions. Here, the

Volumenzufuhr to the pressure source 50a, 50 also via the first valves 15a, 15b (second brake actuation phase) and the ^¬ asked brake pressure does not have to comply with the driver specifications. By supplementing with a pressure measuring device 47 in at least one of the brake circuits I or II (according to the example in Fig. 1 in the brake circuit II behind the valve 18b), the brake system is also suitable for autonomous driving. A brake pressure build-up at the wheel brakes 1-4 also takes place without brake pedal operation by the driver by means of the pressure sources 50a, 50 at a pressure with ^¬ telversorgung via the open first valves 15a, 15b (at closed second valves 14a, 14b; according to the second brake operating phase). The brake system according to the invention for motor vehicles requires no negative pressure. So there must be in the vehicle no Vaku ^¬ umquelle / vacuum source, such as a vacuum pump, be present. The brake system works without a vacuum booster. It is proposed a simple, inexpensive, robust and reliable brake system for hydraulic wheel brakes, which works without vacuum and is suitable for recuperative braking and extensive assistance functions.

The electrically controllable pressure source can be used as electrically operated hydraulic pump of known design, are executed as Kol ^¬ piston pump, or as an electro-hydraulic linear actuator for example.

The brake system for the normal braking and standard vehicle dynamics control functions is displayed with the simplest means at minimal cost.

Since the brake system has only one energy source (except the driver's foot), the hydraulically effective surface of the main ^¬ brake cylinder is preferably chosen so small that in case of failure, a vehicle deceleration well above the legally required deceleration (2.44 m / s ² ) with the legally permitted maximum foot force is possible.

The brake system according to the invention can optionally modular, in the sense of a first unit / module with master cylinder 10 and a separate, second unit / module from the hydrau ^¬ lic and electronic control unit HECU (Hydraulic / Electronic Control Unit, with hydraulic control and Control unit HCU and electronic control unit ECU), or as a single module with master cylinder 10 and HECU (Onebox) be constructed.

By nature, the maximum pedal travel is limited by the vehicle. The volume design of the master cylinder is preferably carried out on the volume requirement that can be achieved. Example:

Volume requirement for full braking (lg) 9 cm ³

 With 500 N foot force achievable delay 0.5g

For this required volume 4.6 cm ³

Preferably, the design of the master cylinder is sought at approximately twice the emergency brake volume with existing pedal travel and the smallest possible master cylinder diameter. Example:

 Master cylinder diameter 19.05 mm

 Total stroke 38.00 mm

Volume output around 10.80 cm ³

In the normal brake case and additional demand for pressure fluid volume for higher brake pressures, the pressure sources get the additional required volume on the invention proposed valves 15a, 15b (via the connections 31a, 31b). Advantages of the invention:

The brake system offers a well-known brake pedal feel and allows a simple response by software, request ^¬ specific adjustable response of a vacuum booster.

 - It is a vacuumless system. This leads to a CO 2 reduction of greater than 1 g / km.

 The brake system can handle relatively few components. The brake system is compact (favorable packaging). The brake system offers weight advantages.

 - The brake system builds on a proven and well-known

Basic system (ESC module 20) and builds on the extent of proven technology. The brake system includes a "power on demand" pressure source (50a / 50b)

reference numeral

 1 wheel brake

2 wheel brake

3 wheel brake

4 wheel brake

5 pressure fluid reservoir 6 first pressure chamber

7 second pressure chamber

8 first master cylinder piston 9 second master cylinder piston 10 master cylinder

12 push rod

13 brake pedal

 14a, 14b second valve

15a, 15b first valve

16a, 16b check valve

17a, 17b low pressure spit

18a, 18b third valve

19 exhaust valve

20 ESC

21 inlet valve

 31a, 31b hydraulic connection

 41 suction connection

 42 pressure connection

45 pressure measuring device

46 position measuring device

47 Pressure measuring device

48 magnet ring

49 displacement sensor element

50a, 50b pump

51 electric motor

60 Brake pedal feel simulator 61 Simulator piston

62 elastic element 63 Elastomer stop

 64 simulator seal

 65 simulator room

 66 passage

 5 70 first spring

 71 Fastenischraube

 72 first connection

 73 second connection

 74 Pressure medium reservoir connection

Claims

Brake system for motor vehicles with

A master cylinder (10) having at least first and second master cylinder pistons (8, 9) arranged one behind the other and defining first and second pressure chambers (6, 7) to each of which a brake circuit (I, II) with wheel brakes (1, 2, 3, 4) is connected, wherein the first master cylinder piston (8) via an actuating forces transmis ^¬ ing push rod (12) with a brake pedal (13) ver ^¬ is connected,

 A pressure medium reservoir (5) associated with the pressure chambers (6, 7), which is under atmospheric pressure,

 • each brake circuit (I, II) of an electrically controllable

Pressure source (50a, 50b) with a suction port (41) and a pressure port (42), wherein the pressure port (42) is connected to the wheel brakes of the brake circuit and wherein the suction port (41) via a second, in particular ^¬ normally closed, valve (14a, 14b) is connected to the master cylinder (10), and

 • each brake circuit (I, II) a third, in particular

 normally open, valve (18a, 18b), via which the master brake cylinder (10) is connected to the wheel brakes of the brake circuit,

characterized in that

each brake circuit (I, II) of the suction port (41) of the pressure source (50a, 50b) via a first, in particular ^normally closed ^¬ closed, valve (15a, 15b) with the Druckmittelvor ^¬ storage container (5) is connected.

Brake system according to claim 1, characterized in that each Brake circuit (I, II) is a low-pressure accumulator (17a, 17b), in particular for receiving pressure medium from the Rad ^¬ brakes, provided, wherein the suction port (41) of the pressure source with the low-pressure accumulator (17a, 17b) is connected.

Brake system according to claim 1 or 2, characterized in that in the second master brake cylinder piston (9) a brake pedal feeler simulator (60) is integrated, which comprises a guided in the second master cylinder piston simulator piston (61) which extends over an elastic element (62). on the second master cylinder piston (9) is supported.

Brake system according to claim 3, characterized in that the brake pedal feel simulator (60) is designed such that the simulator piston (61) upon actuation of the brake pedal (13) is only movable when the second pressure chamber

(7), in particular by means of the first and third valves

(14b, 18b), hydraulically shut off.

Brake system according to one of the preceding claims, characterized in that it comprises no further electrically controllable pressure source.

Method for operating a brake system according to one of claims 1 to 5, characterized in that for establishing brake pressure at the wheel brakes in a second brake actuation phase, the first valves (15a, 15b) are open or are, in particular the second valves (14a, 14b) are closed or become, and the pressure sources are controlled.

A method according to claim 6, characterized in that the second brake operation phase is performed when due to an operation of the brake pedal (13) by the driver

 • A predetermined, second pressure value in the master cylinder, in particular in the second pressure chamber of the master cylinder is achieved or

• a brake pedal operation amount reaches a predetermined second value, in particular the displacement of the first master cylinder piston (8) voted a vorbe ^¬ reaches the second limit value.

A method according to claim 6 or 7, characterized in that a second target output pressure of the pressure source based on a measured pressure of the master cylinder, in particular ^¬ special of the second pressure chamber of the master cylinder, and a second predetermined functional relationship is determined, and that during the second Bremsbetäti ^¬ supply phase of the output pressure of the pressure source is set to the be ^¬ votes second target output pressure.

Method according to one of claims 6 to 8, characterized in that the second brake actuation phase is performed when a braking is requested by an autopilot function, and in particular is no operation of the brake pedal (13) by the driver.

A method according to any one of claims 6 to 9, characterized in that for building up brake pressure at the wheel ^¬ braking on actuation of the brake pedal (13) by a driver in a first brake operating phase, the suction ports (41) of the pressure springs (50a, 50b, 30 ) are connected by means of the second valves (14a, 14b) with the master cylinder (10) or are and the pressure sources are driven become .

11. The method according to claim 10, characterized in that during the first brake actuation phase, the third valves (18a, 18b) are closed.

12. The method according to claim 10 or 11, characterized in that a first target output pressure of the pressure source based on a measured pressure of the master cylinder, in particular ^¬ the second pressure chamber of the master cylinder, a measured brake pedal actuating variable, in particular a measured displacement of the first master cylinder piston (8) , and a first predetermined func ^¬ onal relationship is determined and that during the first brake actuation phase, the pressure sources are controlled to ^¬ such that the output pressure of the pressure sources is set to the specific first target output pressure.

13. The method according to any one of claims 10 to 12, characterized

 characterized in that the first brake actuation phase is performed when, due to the actuation of the

 Brake Pedals (13) by the driver

 A first predetermined pressure value in the master brake cylinder, in particular in the second pressure chamber of the

 Master cylinder, is reached or

• a brake pedal operation amount reaches a first pre ^¬ given value, in particular the displacement of the first master cylinder piston (8) reaches a first predetermined limit value.

14. The method according to any one of claims 6 to 13, characterized in that at the beginning of the actuation of the brake pedal in a preliminary phase, the second and the third valves (18a, 18b, 14a, 14b) are open or are and the pressure sources are not controlled.