WO2014048600A1 - Combined brake system for vehicles, and method for the operation thereof - Google Patents

Abstract

Disclosed is a combined brake system for vehicles, in particular motor vehicles, comprising wheel brakes (9a, 9b) which are assigned to a rear axle (HA) of the vehicle and can each be actuated by an electromechanical actuator (62a, 62b), and a hydraulic brake system for the front axle (VA) of the vehicle, said hydraulic brake system comprising a single-loop master brake cylinder (2) that can be actuated by a brake pedal (1), and hydraulically actuated wheel brakes (8a, 8b) which are assigned to the front axle and are connected to the master brake cylinder (2). The hydraulic brake system for the front axle is in the form of a brake-by-wire brake system that has an electrically controlled pressure supply device (5). Also disclosed is a method for operating such a combined brake system.

Description

Combined brake system for vehicles as well as methods for their operation

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

From WO 2007/014952 AI a combined operating ^¬ brake system for motor vehicles with electromechanically actuated wheel brakes on the wheels of the rear axle and hydraulically actuated wheel brakes on the wheels of the front axle is known. The hydraulically actuated wheel brakes are acted upon by means of a brake pedal operated vacuum brake booster with downstream, single-circuit master cylinder with pressure medium. Since the driver is in the prior art brake system in a normal operation with the hydraulically actuated wheel brakes in conjunction, this brake system for a vehicle with electric vehicle drive, in which the wheels are to be braked at the front by means of regenerative drag torque of the vehicle drive (so-called recuperative or regenerative braking), we ^¬ nig suitable because, for example, when cross-fading or varying the proportion of regenerative drag torque and friction ^¬ braking torque of the hydraulically actuated wheel brakes takes effect on the brake pedal. It is therefore an object of the present invention to provide a

Bereitzu ^¬ brake system and a method for its operation, which / coding for an electrically driven vehicle, in particular for a FEV vehicle (FEV: fully electric vehicle, all-electric vehicle), and insbeson ^¬ particular, the recovery of energy in such a vehicle, especially good suitable is. Also, the brake system or the method should be suitable to an irritation of the vehicle ^¬ leader by repercussions on the brake pedal to verhin ^¬ countries.

This object is achieved by a brake system according to claim 1 and a method according to claim 9 or 10.

The invention is based on the idea, in a combinatorial ^¬ ned brake system with electromechanically operable wheel brakes on the rear axle and hydraulically actuatable wheel ^¬ brake the hydraulic brake system for the front axle as a "brake-by-wire" on the front axle for For -Bremsanlage ^¬ lead. Characterized in that the driver in the normal mode, ie the "brake-by-wire" mode is also decoupled from the front brakes, a recuperative braking is easy and without additional measures, such as the discharge of pressure medium from the front brakes in a low-pressure accumulator , possible, without causing a reaction to the driver.

Preferably, the hydraulic brake system in a "brake-by-wire" mode is controllable both by a driver and independently of the driver, is preferably operated in the "brake-by-wire" mode and can be operated in at least one fallback mode. in which only the operation by the driver is possible.

Both the hydraulically actuated wheel brakes and the electromechanically actuated wheel brakes are preferably designed as a service brake.

The hydraulic brake system for the front axle preferably comprises, in addition to the electrically controllable Druckbereitstel ^¬ treatment device, which actuates the hydraulically actuated wheel brakes in the "brake-by-wire" mode, one between the master cylinder and the hydraulically

operable wheel brakes arranged separating valve for separating the master cylinder of the wheel brakes in a "brake-by-wire" mode and a hydraulically connected to the Hauptbremszy ^¬ linder or connectable simulation ^¬ device with at least one elastic element which in the "brake-by- wire "mode gives the driver a pleasant brake pedal feel and is switched on and off ^¬ switchable. By the controllable separation of the connection from the master cylinder to wheel brakes, as well as the brake master cylinder to the simulation device to the driver, a Bremspe ^¬ dalgefühl in the 'brake-by-wire "mode, irrespective of the brake pressures are provided in the wheel brakes. Particularly preferred is the elekt ^¬ driven controllable pressure supply device by means of a Zuschaltventils with the hydraulically actuated Rad ^¬ brakes connectable.

In order to achieve the fastest possible and precise pressure position on the hydraulically actuated wheel brakes, the pressure-providing device is preferably provided by a cylinder-piston arrangement with a hydraulic pressure chamber. forms, the piston is actuated by an electromechanical Aktua- tor.

According to a preferred embodiment of the invention, the brake system comprises a first electronic control unit, by means of which the hydraulic brake system is controlled for the front axle, and at least a second electronic control unit, by wel ^¬ cher at least one electromechanical actuator of a wheel brake of the rear axle is controlled, wherein the first and the second control and regulating unit are arranged spatially separated and are connected via a communication link with each other. In this way, the electro-hydraulic unit of the hydraulic brake system can be performed from smaller ^¬ and the second electronic control and Re ^¬ gel unit ^¬ be integrally arranged in the vicinity of the to be driven actuator. The Ready to Print Stel ^¬ development facility, the release valve and the supply valve are controlled particularly preferred gel unit by the first electronic control and Re ^¬.

Preferably, the brake system per electromechanically actuable wheel brake comprises a second electronic control and regulating unit, which is arranged in the vicinity of the wheel brake.

To set the braking forces on the wheel brakes according to the driver's braking request, the brake system comprises a detection ^¬ device for detecting an operation of the brake pedal representing size, wherein the detection device via the first control and regulating unit and the second control unit with electrical Ener ^¬ gie is available. Even if one of the tax and Control units thus the braking request can be detected. Particularly preferably, an actuating travel of a piston of the master cylinder is detected.

In order to increase the availability of the braking system, is before Trains t ^¬ for the hydraulic braking system, advantageously provided at least for the first control unit and for each electromechanical actuator of the wheel brakes of the rear axle an own electric power supply source.

The simulation device preferably has a hydraulic simulator chamber, which is hydraulically connected by means of a hydraulic connection to the pressure chamber of the master brake cylinder by means of a simulator release valve.

According to one embodiment of the invention, the vehicle is equipped with at least one electric vehicle drive ^¬ , wherein the wheels are braked on at least one axis by means of regenerative drag torque of the vehicle drive and friction braking torque of the corresponding wheel brakes. Particularly preferably, the wheels of the front axle with the hydraulically actuated wheel brakes are additionally recuperative braked.

Preferably, at least one electromechanical

operable wheel brake a parking brake device, wel ^¬ che is controlled by means of a parking brake control element. Particularly preferably, all electromechanically actuable wheel brakes comprise such a parking brake device. The parking brake control element is preferably connected to the ^¬ ers te control unit. The brake system according to the invention has the advantage that it can be used both in vehicles with electric Vorderachsantrieb (recuperation on the front axle) and in vehicles with electric Hinterachsantrieb (recuperation on the rear axle) without changing the structure.

The invention also relates to a method for operating a brake system according to the invention. In this case, in a "brake-by-wire" mode, the electromechanical actuators and the pressure supply device are actuated in accordance with the braking demand applied to the brake pedal by a vehicle driver detects an operation of the brake pedal representing size actuated.

The invention further relates to a method for operating a brake system according to the invention, wherein in a "brake-by-wire" mode a driver is separated from the wheel brakes by means of a zwi ^¬ rule master cylinder and hydraulically actuated wheel brakes separating the master cylinder with a simulation ^¬ device is connected to at least one elastic element, so that the driver a pleasant brake ^¬ pedal feeling is taught, and the hydraulic

operable wheel brakes are hydraulically connected to an electrically controllable pressure supply device.

The invention further relates to the use of a combined brake system according to the invention in a fully electric vehicle with an electric vehicle drive.

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

It show schematically

Fig. 1 shows an embodiment of an inventive

 Brake system, and

Fig. 2 is a diagram for illustrating an embodiment of a method according to the invention for operating a brake system.

In Fig. 1, an embodiment of an inventive ^¬ Shen brake system is shown schematically. The brake system comprises firstly hydraulically actuated wheel brakes 8a, 8b and on the other hand, electromechanically operable Radbrem ^¬ sen 9a, 9b. The hydraulically operated wheel brakes 8a, 8b are arranged on the front axle VA of the vehicle (FR: front right wheel, FL: front left wheel) on which changing the rear ^¬ se HA of the vehicle electromechanically operable wheel are braking ^¬ 9a, 9b (RR: rear right wheel, RL: left rear wheel ^¬ ), which are actuated in accordance with the by a vehicle ^¬ leader on a brake pedal 1 controlled braking request and / or in accordance with the hydraulic pressure in the hydraulically actuated wheel brakes 8a, 8b actuated hydraulic pressure. Both the hydraulically and the electromechanically operable wheel brakes 8a, 8b, 9a, 9b are designed as service brakes of the vehicle. The hydraulic service braking system for the front axle VA is designed as a "brake-by-wire" -Bremsanlage. It is in a "brake-by-wire" mode, both the driving ^¬ generating leader as well as independently of the vehicle operator

can be controlled, is preferably operated in the "brake-by-wire" mode and can be operated in at least one fall-back mode, in which only operation by the driver is possible, so the brake-by-wire mode provides the normal brake function the braking ^¬ system in which the driver is decoupled from the hydraulically actuated wheel brakes 8a, 8b and the hydraulically actuated wheel brakes 8a, 8b are actuated by an electrically controllable pressure supply device 5. Only in certain situations, such as a failure of the electrical power supply of the pressure supply device 5, the hydraulic part of the brake system is operated in a fallback mode, wel ^¬ cher the driver is connected to the hydraulically actuated wheel brakes 8a, 8b and so directly pressure in the wheel brakes 8a, 8b can build.

The hydraulic part of the braking system comprises essentially a beispielsge ^¬ Mäss means of the brake pedal 1

actuatable hydraulic actuation unit 2, a travel simulator (or simulation device) 3 acting together with the hydraulic actuation unit 2, a pressure medium reservoir 4 assigned to the hydraulic actuation unit 2, an electrically controllable pressure supply reservoir 5, wheel brake pressure modulation valves 6a, 6b, 7a, 7b and a first electronic control unit 12.

According to the example, the brake system comprises each hydraulic operable wheel brake 8a, 8b, an inlet valve 6a, 6b and an exhaust valve 7a, 7b, which are hydraulically interconnected in pairs via Mittenan ^{¬ connections} and connected to the Radbrem ^¬ sen 8a, 8b. The input terminals of the intake valves 6a, 6b by means of a Bremskreisver ^¬ supply line 13 supplied with pressures derived in the "brake-by-wire" mode from a system pressure ^¬ to that in a in a pressure chamber 37 of the electrically controllable pressure supply device 5 In the fallback mode, the brake circuit supply line 13 is acted upon via a hydraulic line 22 with the pressure of the pressure chamber 17 of the actuator unit 2. The output ^{terminals of} Auslassven ^¬ tile 7 a, 7 b are connected via a return line 14 with the

Pressure medium reservoir 4 connected. To detect the pressure prevailing in the system pressure line 38, a preferably redundantly designed pressure sensor 19 is provided.

The hydraulic actuating unit 2 has in a Ge ^¬ housing 16 a piston 15 which limits a hydraulic chamber or a pressure chamber 17, and provides a

The pressure chamber 17 is connected on the one hand via formed in the piston 15 radial Boh ^¬ ments and a corresponding pressure equalization line 41 with the pressure medium reservoir 4, which can be shut off by a relative movement of the piston 17 in the housing 16, and on the other hand by means of hydrauli ^¬ lines 22 with the already mentioned brake circuit supply line 13 in connection, via which the inlet valves 6a, 6b are connected to the actuator unit 2. In this case, in the pressure equalization line 41, a parallel circuit of a normally open (SO) diagnosis valve 28 with a pressure medium reservoir 4 toward closing check valve 27 is included. The pressure chamber 17 receives an unspecified return spring, which positions the piston 15 when the master cylinder 2 is not actuated in a starting position. A piston rod 24 couples the

Pivoting movement of the brake pedal 1 as a result of a Pedalbetä ^¬ tion with the translational movement of the (master cylinder) piston 15, whose actuation path is detected by a preference ^¬ redundantly designed displacement sensor 25. Since ^¬ by the corresponding Kolbenwegsignal is a measure of the brake pedal depression angle. It represents a brake ^¬ wishes of the driver.

In the connected to the pressure chamber 17 line section 22, a separating valve 23 is arranged, which is designed as an electrically actuated, preferably normally open (SO), 2/2-way valve. By Trennven ^¬ til 23, the hydraulic connection between the pressure chamber 17 and the brake circuit supply line 13 can be shut off. A connected to the line section 22 pressure sensor 20 detects the built-up in the pressure chamber 17 by a displacement of the piston 15 pressure. This pressure also represents a measure of the braking request of the driver.

The electrically controllable pressure supply device 5 is designed as a hydraulic cylinder-piston arrangement or a single-circuit electro-hydraulic actuator (linear actuator), the piston 36 of a schematically indicated electric motor 35 with the interposition of a rotation also schematically shown Translationsgetriebes 39 can be actuated. One of the detection of the rotor position of the electric motor 35 serving, only schematically indicated rotor position sensor is designated by the reference numeral 44. In addition, a temperature sensor 45 for sensing the temperature of the motor winding may also be used. The piston 36 limits the pressure chamber 37.

The actuator pressure generated by the force effect of the piston 36 on the pressure medium enclosed in the pressure chamber 37 actuator pressure is fed into the system pressure line 38 and detected with the system pressure sensor 19. In the "brake-by-Wire" - mode, the system pressure line 38 will shift valve connected to the to ^¬ 26 with the brake circuit supply line 13. In this way, a Radbremsdruckauf- establishment and termination for the wheel brakes is carried out at a normal braking 8a, 8b flows when pressure reduction.. here, the previously from the pressure chamber 37 of the actuator 5 in the wheel brakes 8a, 8b displaced pressure medium in the same way again in the pressure chamber 37 of the actuator 5 returns. in contrast, flows during a braking operation with each individual wheel differently, using the Mo ^¬ dulationsventile 6a, 6b , 7a, 7b regulated wheel brake of the discharged via the outlet valves 7a, 7b pressure medium ^¬ share in the pressure fluid reservoir 4. A sucking of pressure medium in the pressure chamber 37 is possible by a return of the piston 36 with closed Zuschaltventil 26 by pressure fluid from the container 4 via the line 42 with an opening than in the flow direction to the actuator check valve au S formed Nachsaugventil 40 can flow into the Akuatordruckraum 37.

Simulation device 3 is hydraulically coupled to the master cylinder 2. Simulation device 3 consists in Essentially from a simulator chamber 29, a simulator rear chamber 30 and a simulator piston 31 separating the two chambers 29, 30 from one another.

Simulator piston 31 is supported by a in

Simulatorrückkammer 30 arranged elastic element 33 (eg simulator spring) on the housing 16 from. The simulator chamber 29 is connected by means such as an electrically operable simulator release valve 32 with the pressure chamber 17 of the main brake cylinder ^¬. 2 A check valve 34 arranged hydraulically antiparallel to the simulator ^release valve 32 makes it possible to operate the check valve 34 independently of the switching state

Simulatorfreigabeventils 32 a largely unhindered backflow of the pressure medium from the simulator chamber 29 to the master cylinder pressure chamber 17th

The first electronic control unit 12 serves at least to control the electrically actuatable components of the hydraulic part of the brake system, in particular the valves 6a-6b, 7a-7b, 23, 26, 28, 32 and

Electric motor 35 of the pressure supply device 5. The signals of the sensors 19, 20, 25 and 44 are also ver ^¬ works at least in the electronic control unit 12.

As already mentioned, the rear axle HA are associated with the wheel brakes 9a, 9b whose actuation takes place in accordance with the hydraulic pressure applied in the hydraulically actuatable wheel brakes 8a, 8b of the front axle VA by means of electromechanical actuators. The mentioned hydraulic pressure can, depending on the mode of operation, be determined with the aid of the pressure sensors 19, 20. Based on this pressure value ^¬ which the electromechanically operable wheel brakes 9a, 9b is driven, that is, in consideration of a braking-force Distribution function between the front and rear axle is an application force of the wheel brakes 9a, 9b set. Except the ^¬ can electromechanically actuatable brake 9a, 9b according to the driver's desire to brake, shown, for example in accordance with the detected displacement sensor 25 by means of piston travel, are driven. The control of the wheel brakes 9a, 9b is, for example decentralized by each one of the wheel brake 9a, 9b arranged, eg in / to the actuator inte ^¬ grated, electronic control and regulation unit 10a, 10b made. However, it is also possible that a central, the rear axle associated electronic control unit (control unit 70 in Fig. 2) for both electromechanical actuators of the wheel brakes 9a, 9b is present. The control and regulation units 10a, 10b or the control and regulation unit 70 of the electromechanically actuatable wheel brakes 9a, 9b are / is in communication with the first control unit 12.

The exemplary brake system is equipped with a parking brake functionality ^¬ . For this purpose, the electromechanically actuable wheel brakes 9a, 9b parking brake devices, not shown, with which the wheel brakes 9a, 9b are locked in the applied state. The parking brake devices, for example, by means of a control element, which is connected for example to the first control and regulating unit 12, controlled by the driver.

The (entire) brake system 51 is connected via the push rod 24 to the brake pedal 1 and ultimately to the driver.

2 is a very schematic diagram for clarification. Chung of an embodiment of a method according to the invention for operating a brake system shown. In the 'brake-by-wire "mode, a via the brake pedal 1 is applied by the vehicle operator driver's braking request is detected 50 of the central, first electronic control unit 12 by means of the preferably integrated Redun ^¬ dant pedal travel sensor 25 (path s) and therefrom, for example by means of a predetermined pressure-displacement characteristics (pressure boosting characteristic) 52, a target pressure value P _soll is determined for the pressure supply device 5 of the hydraulic wheel brakes of the front axle VA. the in the control and Re ^¬ gel unit 12 stored print gain characteristic 52 for the front axle VA advantageously corresponds to the idea ^¬ len brake force distribution to the rear axle HA. the actual pressure P ist of the pressure supply device 5 is sensed by the pressure sensor 19. By means of an engine control unit 53 is the actual pressure P _is in accordance with the target pressure P _So ii adjusted. block 54 illustrates schematically the control of the electrically actuatable valves 6a, 6b, 7a, 7b, 23, 26 and 32 for acting on the wheel brakes 8a, 8b for the right front wheel (FR) and the left front wheel (FL) with pressure ^¬ medium. In the "brake-by-wire" mode, the master cylinder 2 via the opened

Simulatorfreigabeventil 32 hydraulically connected to the simulation device 3. At the same time, the driver is hydraulically decoupled from the front ^¬ axle wheel brakes by the now closed isolation valve 23 and the pressure is provided via the open connection valve 26 of the Druckbereits ^¬ positioning device available. A wheel-specific brake pressure control is possible, for example via the intake and exhaust valves 6a, 6b, 7a, 7b. The wheels FR, FL of the front axle VA has not shown wheel speed ^¬ sensors, which in case of need by the control and Control unit 12 performed slip control (eg

Anti-lock control).

The first control unit 12 has advantageously ^¬ legally its own electrical power supply ^¬ source (power supply battery) 55th

Optionally, the control and regulation unit 12 has an interface 56 to an environment sensor system to perform active safety functions can.

The vehicle is advantageously equipped with an electric vehicle drive 80 (electric motor), wherein the wheels can be braked on at least one axis by means of regenerative drag torque of the vehicle drive and friction braking torque of the corresponding wheel brakes. The control unit 12 then comprises a further interface 57 to an engine management system of the vehicle drive 80, to perform the recuperation of the brake system with appropriate distri ^¬ development of the braking torque to drag moment and Reibbremsmo ^¬ ment. Since most of the vehicles on the front wheels require greater braking force during braking, and because the front wheel brakes 8a, 8b of the hydraulic brake-by-wire brake system are in brake-by-wire operation by the master brake cylinder 2 and thus a reaction are decoupled on the driver, the wheels on the front axle VA are recuperative braking ge ^{¬ ¬} advantageous way legally. Thus, a change in the ratio / proportion of recuperative and friction braking torque on the front wheels without a reaction to the driver or the

Brake pedal 1 simply possible.

The electromechanical actuators 62a, 62b for the wheel brake 9a, 9b of the rear axle HA is, as already described above, he imagines ^¬, a second electronic control unit 70 assigned, which can communicate via an electrical interface 58 with the first control unit 12th The electromechanical actuators 62a, 62b and possibly locally arranged engine control units 61a, 61b preferably each have a separate electric Energiever ^¬ sorgungsquelle (battery) 59, 60. The second control unit 70 may be supplied by one or both of power supplies 59, 60 become.

Preferably, the displacement sensor 25 is ver ^¬ provides parallel to its Ener ^¬ gieversorgung via the control unit 12 via the control unit 70 with electrical energy so that when a malfunction of the control and Re ^¬ gel unit 12, the displacement sensor 25 continues to measure is the brake pedal operation available so that s of the displacement sensor 25 is an actuation of the wheel brakes elektrome ^¬ chanical 9a, 9b is possible based on the displacement signal. The wheel brakes 8a, 8b of the front axle VA are in this case error

(Control unit 12 passive) only braked by the pressure applied by the driver. In this non-reinforced hydraulic fallback mode of operation, the vehicle operator is hydraulically operatively connected through the open isolation valve 23 to the front of the axis ^¬-wheel brakes 8a, 8b (brake circuit supply line 13). The simulation device 3 or the pressure supply device 5 are hydraulically separated from the brake circuit supply line 13 by means of the normally closed simulator release valve 32 or the normally closed connection valve 26.

In the control and regulation unit 70 is a on the rear axle ^¬ HA according to the ideal brake force distribution fitted brake booster characteristic 63 predetermined, which describes the relationship between the brake pedal operation (path s) and to be generated by the electromechanical actuator 62a and 62b Zuspannkraft F _So ii. The

Istzuspannkraft F _Ist ^RR , F _Is ^RL each actuator 62a and 62b, for example, via a force sensor 64a, 64b sensed and adjusted via the two engine control units 61a, 61b according to the wheel individual setpoint input F _So ii ^RR , F _So ii ^RL . Advantageously, the characteristic curve 63 is adapted to delay and Rekuperationszustand of Fahrzeu ^¬ sat.

The wheels of the rear axle HA also have not shown wheel speed sensors that activate the Schlupfregier the control unit 70 in the demand ^¬ case.

Claims

Claims:

1. Combined brake system for vehicles, in particular

Motor vehicles, with a rear axle (HA) of the vehicle ^¬ assigned, each actuated by an electromechanical actuator (62a, 62b) wheel brakes (9a, 9b) and with a hydraulic brake system for the front axle (VA) of the vehicle, which by means of a brake pedal (1) actuated, single-circuit main ^¬ brake cylinder (2) and to this is connected, the front axle associated, hydraulically operated wheel ^¬ brakes (8a, 8b), characterized in that the hydraulic brake system for the front axle as a "brake- By-wire "-Bremsanlage with an electrically controllable pressure supply device (5) is executed.

2. Combined brake system according to claim 1, characterized in that the hydraulic brake system for the front axle between the master cylinder (2) and the hydraulically actuated wheel brakes (8a, 8b) arranged separating valve for separating the master cylinder (2) from the wheel brakes (8a, 8b) in a "brake-by-wire" mode, one (the master cylinder 2) is hydraulically connected or connectable Simulati ^¬ onseinrichtung (3) with at least one elastic element (33) which 'brake-by-wire "in the ; mode is the vehicle operator imparts a pleasant brake pedal feel and executed switched on and off, and the electrically controllable pressure supply device (5) which the hyd ^¬ raulisch actuated wheel brakes in the 'brake-by-wire "mode (8a, 8b) operates, in particular by means of a connection valve (26) with the hydraulically actuated wheel brakes (8a, 8b) is connected comprises.

3. Combined brake system according to claim 2, characterized in that the pressure supply device

(5) is formed by a cylinder-piston arrangement with a hydraulic pressure chamber (37), the piston

(36) by an electromechanical actuator (35, 39) is actuated.

4. Combined brake system according to one of claims 1 to 3, characterized in that the brake system, a first electronic control unit (12), with ^{¬ means} which the hydraulic brake system for the pre ^¬ derachse, in particular the pressure supply device (5) Disconnect valve (23) and the Zuschaltventil (26) is driven, and at least a second electronic control unit (10a, 10b, 70), by means of which at least one electromechanical actuator (62a, 62b) of a wheel brake (9a, 9b) of Behind ^¬ axis is controlled comprises, wherein the first and the second control and regulating unit are arranged spatially separated and connected via a communication link (58) with each other.

5. Combined brake system according to claim 4, characterized in that a detection device (25) for detecting an operation of the brake pedal (1) re ^¬ presenting size, in particular for detecting an actuation path of a piston (15) of the Hauptbremszylin ^¬ DERS (2), is provided, wherein the detection means (25) via the first control unit (12) and the second control unit (10a, 10b; 70) can be supplied with electrical energy.

6. Combined brake system according to one of claims 1 to 5, characterized in that for the hydraulic brake system, in particular for the first control and Re ^¬ geleinheit (12), and for each electromechanical Actuator (62a, 62b) of the wheel brakes ( 9a, 9b) of the rear axle its own electrical power source (55, 59, 60) is provided.

Combined Brake system according to one of claims 1 to 6, characterized in that the simulation device (3) has a hydraulic simulator chamber (29) has ^¬ which via a hydraulic connection with the pressure chamber (17) of the main brake cylinder (2) is hydraulically (by means of a simulator release valve 32) is separably connected.

Combined Brake system according to one of claims 1 to 7, characterized in that the vehicle min ^¬ is ^¬ least equips an electric vehicle drive (80), wherein the wheels on at least one axis, in particular the front axle (VA), by means of

 regenerative drag torque of the vehicle drive (80) and friction brake torque of the corresponding, in particular hydraulically actuated, wheel brakes (8a, 8b, 9a, 9b) are braked.

9. A method for operating a combined brake system according to one of claims 1 to 8, characterized in that in a "brake-by-wire" mode, the electromechanical actuators (62a, 62b) and the pressure supply device (5) in accordance with by a vehicle driver on the brake pedal (1) applied brake requirement, in particular in accordance with output signals of a detection device (25) which detects an operation of the brake pedal (1) repre ^¬ sentierende size, are operated.

Method for operating a combined braking system according to any one of claims 1 to 8, in particular procedural ^¬ ren according to claim 9, characterized in that in a 'brake-by-wire' mode a vehicle operator by means of a between the master brake cylinder (2) and hydraulically operable brakes (8a, 8b) arranged separating valve (23) is separated from the wheel brakes, the master cylinder (2) with a simulation device (3) with at least one elastic element (33) ver ^¬ prevented, so that the driver a pleasant brake pedal feeling is mediated, and the hydraulically actuable wheel brakes (8a, 8b) are hydraulically connected to an electrically controllable pressure supply device (5).

Use of a combined brake system according to one of Claims 1 to 9 in an all-electric vehicle with an electric vehicle drive (80).