EP1750984A1

EP1750984A1 - Method for braking a vehicle by means of a fluidically triggered vehicle brake system, and vehicle brake system

Info

Publication number: EP1750984A1
Application number: EP05754196A
Authority: EP
Inventors: Josef Knechtges; Frank Heller; Jan Grundmann; Christian Chemnitz
Original assignee: Lucas Automotive GmbH
Current assignee: ZF Active Safety GmbH
Priority date: 2004-05-24
Filing date: 2005-05-19
Publication date: 2007-02-14
Also published as: WO2005115816A1; JP2008500217A; KR20070026526A; US7654619B2; DE102004025402B4; DE102004025402A1; CN1956869A; CN100475620C; US20080061624A1

Abstract

Disclosed is a method for braking a vehicle by means of a fluidically triggered vehicle brake system (10) which is provided with one respective fluidically triggered brake unit (28, 30, 32, 34) that is assigned to a vehicle wheel and is fluidically coupled to a brake force generator (16, 26) via at least one fluid circuit (12, 14). A pumping mechanism (52) by means of which at least one of the brake units (28, 30, 32, 34) can be fed with brake fluid regardless of whether the brake force generator (16, 26) is activated, is provided in the at least one fluid circuit (12, 14) in order to convey brake fluid. Control valves (58, 60, 62, 64) by means of which the brake force generator (16, 26) can be fluidically coupled to and disconnected from the brake units (28, 30, 32, 34) and the pumping mechanism (52) are provided in the fluid circuit (12, 14). In order to comfortably create a parking brake condition, the following steps are carried out: A) a fluid pressure is built up in the at least one fluid circuit (12, 14) via the brake force generator (16, 26) such that at least two of the brake units (28, 30, 32, 34) are fluidically triggered; B) the brake force generator (16, 26) is disconnected from the brake units (28, 30, 32, 34) and the pumping mechanism (52) by closing the control valves (58, 60, 62, 64); C) the pumping mechanism is activated (in two brake units) and brake fluid is conveyed from one of the at least two brake units (30, 32) to the other one of the at least two brake units (28, 34), respectively.

Description

Method for braking a vehicle by means of a fluidically controllable vehicle brake system and vehicle brake system

TECHNICAL FIELD OF THE INVENTION

The present invention relates to a method for braking a vehicle by means of a fluidically controllable vehicle brake system and a corresponding vehicle brake system, the vehicle brake system each having a fluidically controllable brake unit assigned to a vehicle wheel, which is fluidically coupled to a brake force generator via at least one fluid circuit, in which at least one Fluid circuit, a pump device for conveying brake fluid is provided, by means of which at least one of the brake units can be supplied with brake fluid regardless of an activation of the brake force generator, and wherein control valves are provided in the fluid circuit, by means of which the brake force generator can be fluidly coupled to the brake units and the pump device and can be decoupled from them.

STATE OF THE ART

Such a vehicle brake system is known from the prior art. Document DE 101 10 658 C1 shows a hydraulic vehicle brake system in which two separate fluid circuits can be supplied with brake fluid via a master brake cylinder. Two brake units are assigned to each fluid circuit, a brake unit of a front wheel and a brake unit of a rear wheel. Control valves are provided to control the respective brake units. In addition, a pump device is assigned to both fluid circuits, by means of which the brake units can be controlled independently of pressure generation via the master brake cylinder. This makes it possible to implement electronic control systems, such as an electronic stability program (ESP).

In order to be able to implement a parking brake effect in addition to the functionalities of such a vehicle brake system described in document DE 101 10 658 Cl for the case of service braking, it is also known from the prior art that built on the master brake cylinder and on the individual brake units exploiting acting fluid pressure to bring about a parking brake condition. For this purpose, for example, the brake fluid supplied to the brake units of the vehicle wheels of the front axle is conveyed via the pump device from the brake units of the front axle to the brake units of the rear axle and then the brake units of the rear axle are mechanically locked. In conventional vehicle brake systems, this occurs in a state in which a certain brake pressure is still built up via the master brake cylinder, for example by the driver of the vehicle depressing the brake pedal permanently. However, this in turn means that there is a direct fluidic connection between the master brake cylinder and the brake units during the activation of the parking brake effect. As a result, vibrations and noises that occur when the pump device is activated to bring about the parking brake state are transmitted directly into the vehicle interior via the master brake cylinder, the brake booster and the brake pedal connected to it, which can be perceived as disturbing by the driver and other occupants of the vehicle. In addition, the activation of the pump device inevitably also removes brake fluid from the master brake cylinder, so that the brake pedal yields under the pedal actuation force exerted by the driver of the vehicle, which the driver feels and could find uncomfortable or at least unfamiliar.

OBJECT AND SOLUTION ACCORDING TO THE INVENTION

In contrast, it is an object of the present invention to provide a method and a vehicle brake system of the type described in the introduction, in which the parking brake function can be activated with simple technical means and with the avoidance of disruptive influences in the vehicle interior.

This object is achieved by a method of the type described in the introduction, in which the following steps are carried out to bring about a parking brake state:

A) building up a fluid pressure via the braking force generator in the at least one fluid circuit, so that at least two of the braking units are actuated fluidically;

B) decoupling the braking force generator from the braking units and the pump device by closing the control valves; C) Activating the pump device and delivering brake fluid from one of the at least two brake units to the other of the at least two brake units.

According to the invention, as already described at the beginning of the prior art, a fluid pressure, which can be detected by means of a fluid sensor, is built up in the at least one fluid circuit via the braking force generator, so that a braking effect is achieved on the at least two braking units, i.e. these are tightened. As a result, however, the fluidic connection between the braking force generator and the rest of the respective fluid circuit is then interrupted, so that activation of the pump device and resulting pressure fluctuations or vibrations in the fluid circuit cannot spread into the braking force generator. Only after the control valves have been closed is the pump device activated and subsequently brake fluid is conveyed via the pump device from one brake unit of the fluid circuit to the other brake unit of the fluid circuit. The method according to the invention thus ensures that the action of the pump device neither leads to disturbing noises in the vehicle interior nor to an unusual relenting of the brake pedal.

If in the context of the description and the claims for the present invention a "braking force generator" is mentioned, this expression is intended to mean both an arrangement in which a fluid pressure in the at least one fluid circuit is generated via a brake pedal, a brake booster and a master brake cylinder connected to it will also include an arrangement in which a brake pedal actuation is detected and in accordance with the latter then a fluid pressure is generated in the at least one fluid circuit without directly utilizing the pedal actuation force exerted on the brake pedal. Furthermore, the expression “brake force generator” is also intended to include such arrangements, who use the pedal actuation force exerted on the brake pedal only partially or only in certain (emergency) operating situations.

DEVELOPMENTS OF THE INVENTION

A further development of the present invention provides that the pump device is controlled in accordance with certain parameters, for example the vehicle inclination and / and the vehicle weight or / and the wheel speed or / and the operating position of a parking brake switch and / or the brake pedal actuation or / and the yaw rate or / and the lateral acceleration or / and the fluid pressure generated by the braking force generator. With regard to activation of the parking brake function, it is thus possible to prevent it until the speed output by each of the wheel sensors has dropped to a specific limit value or even to zero. In addition, it is possible to determine a minimum fluid pressure based on the vehicle inclination and the current vehicle weight, at which an unintentional rolling away of the vehicle is excluded.

As already indicated above, it may be necessary, depending on the current operating situation of the vehicle, for example when parking the vehicle on a steeply inclined roadway, that the fluid pressure on the brake units fluidically controlled to achieve the parking brake action is to be increased significantly. In order to be able to provide a sufficient amount of hydraulic fluid which is then conveyed via the pump device to the respectively controlled brake unit, a further development of the invention provides that at least one fluid reservoir is assigned to each of the fluid circuits. The fluid reservoir can thus in each case be filled with brake fluid in states in which a sufficiently high fluid pressure is available, this brake fluid then being able to be removed again if necessary. Thus, according to the invention, it is possible for the brake fluid, which may be pressurized, to be temporarily stored in the fluid reservoir and for the pump device to deliver it to the other brake unit in step C).

If you take up the operating situation mentioned above in which the vehicle is to be parked on a steeply inclined road, the driver may feel that the pedal actuation force exerted on the brake pedal and the resulting fluid pressure in the at least a fluid circuit is not sufficient to safely park the vehicle. For example, the vehicle continues to roll at low speed despite the brake pedal being depressed. In this state, the driver will continue to depress the brake pedal in order to build up a higher fluid pressure in the at least one fluid circuit and ultimately increase the braking force. In order to take this operating situation into account, a further development of the invention provides that when the fluid pressure is increased by the braking force generator during step B), the control valves are activated in such a way that further braking fluid from the braking force generator is temporarily stored in the fluid reservoir and then the braking force generator from the brake units and the pump device by closing the control valves is decoupled. By means of this measure according to the invention, the fluid pressure additionally generated in the braking force generator can also be used to activate the parking brake function.

In this context, an advantageous further development of the invention provides that the control valves are activated according to a pulse method, for example a pulse width modulation method. With such a pulse width modulation method, the opening or closing pulse width of the respective control valve can be varied within a period of time. This makes it possible to close the respective control valve with a holding force which corresponds to the fluid pressure at the start of the activation of the parking brake function.

With regard to the pump device, it can be provided according to the invention that it is designed as a return pump in the fluid circuit, in particular as part of an electronic control system, for example an electronic stability system and / and an anti-lock system and / and a traction control system and / and an automatic speed control system , A pump device which is already present in the brake system can therefore be used to implement the invention.

An advantageous embodiment of the invention provides that two fluid circuits are provided, each fluid circuit being fluidly coupled to a brake unit assigned to a front wheel and to a brake unit assigned to a rear wheel. Furthermore, it can be provided that the vehicle wheels respectively assigned to a fluid circuit are arranged diagonally on the vehicle. In this connection, it can further be provided according to the invention that brake fluid is conveyed from the front wheel to the rear wheel in step C).

The invention further relates to a vehicle brake system, each having a fluidically controllable brake unit assigned to a vehicle wheel, which is fluidically coupled to a braking force generator via at least one fluid circuit, a pump device for conveying brake fluid being provided in the at least one fluid circuit, by means of which, independently of an activation of the Brake force generator at least one of the brake units can be supplied with brake fluid, and wherein control valves are provided in the fluid circuit, by means of which the brake force generator can be fluidically coupled to and decoupled from the brake units and the pump device. In this vehicle brake system is According to the invention, it is provided that, in order to bring about a parking brake state, the braking force generator builds up a fluid pressure in the at least one fluid circuit in order to fluidly control at least two of the braking units, that the control valves can also be controlled such that the braking force generator is fluidly decoupled from the braking units and the pump device and that after the fluidic decoupling of the braking force generator, the pump device conveys brake fluid from one of the at least two braking units to the other of the at least two braking units.

According to a development of the present invention, the vehicle brake system has sensors for determining the vehicle inclination and / and the vehicle weight or / and the wheel speed or / and an operating position of a parking brake switch or / and the current deflection of a brake pedal or / and the lateral acceleration of the vehicle or / and Yaw rate of the vehicle and / or the fluid pressure generated by the braking force generator.

The vehicle brake system according to the invention is preferably designed such that at least one fluid reservoir is assigned to each of the fluid circuits.

An exemplary embodiment of the present invention is explained below with reference to the accompanying figures. They represent:

BRIEF DESCRIPTION OF THE DRAWINGS

Fig. 1 is a schematic representation of a vehicle brake system according to the invention and

Fig. 2 is a flow chart to explain the method according to the invention.

DESCRIPTION OF A PREFERRED EMBODIMENT

An embodiment of a vehicle brake system according to the invention is generally designated 10 in FIG. 1. This comprises a first fluid circuit 12 and a second fluid circuit 14. The two fluid circuits 12 and 14 are fluidly coupled to a tandem master brake cylinder 16, the fluid circuit 12 being supplied with brake fluid by displacing a secondary piston 18 from a secondary pressure chamber 20, and the fluid circuit 14 by moving a primary piston 22 is fed with brake fluid from a primary pressure chamber 24. The master brake cylinder 16 is coupled in a conventional manner to a vacuum brake booster 26 which can be actuated via a brake pedal, not shown.

The fluid circuits 12 and 14 are fluidly connected to brake units 28, 30, 32, 34, the brake unit 28 being assigned to the left rear wheel, the brake unit 30 to the right front wheel, the brake unit 32 to the left front wheel and the brake unit 34 to the right rear wheel of the vehicle , This assignment is a so-called diagonal division. Likewise, according to the invention, other divisions can also be present, for example a front-axle-rear-axle division.

Each brake unit 28, 30, 32, 34 is assigned an inlet valve 36, 38, 40, 42, which can be controlled separately via an electronic control unit (not shown). Furthermore, each brake unit 28, 30, 32, 34 is assigned an outlet valve 44, 46, 48, 50, which can also be controlled separately via the electronic control unit. Both fluid circuits 12 and 14 are fluidly coupled to a pump device 52. An ABS or ESP functionality can be implemented, for example, via the inlet valves 36, 38, 40, 42, the outlet valves 44, 46, 48, 50 and the pump device 52. The inlet valves 36, 38, 40, 42 are actuated using a PWM (pulse width modulation) method. This results in a high degree of variability in the control of these control valves.

Each of the fluid circuits 12 and 14 is also provided with a fluid reservoir 54 and 56, in which brake fluid can be temporarily stored under pressure, if necessary.

Finally, each of the fluid circuits 12 and 14 is associated with a pair of control valves 58 and 60 and 62 and 64. The control valves 58, 60, 62 and 64 can also be controlled separately via the electronic control unit using a PWM (pulse width modulation) method, so that a high degree of variability can be achieved in the control of these control valves. The control valves 58, 60, 62 and 64 are arranged in the two fluid circuits 12 and 14 as follows: the control valves 58 and 60 are assigned to the fluid circuit 12 and thus to the brake units 28 and 30; the control valves 62 and 64 are assigned to the fluid circuit 14 and thus to the brake units 32 and 34. This arrangement makes it possible to fluidly decouple the individual brake units 28, 30, 32 and 34 from the master brake cylinder 16, so that an activation of the pump device 52 and a resulting circulation of brake fluid in the individual fluid circuits 12 and 14 has no effect on the master brake cylinder 16.

1 also shows that a pressure sensor 66 is arranged in the fluid circuit 14. 1 also shows a series of check valves and two pressure relief valves 68 and 70, one of which is assigned to the fluid circuit 12 and the other to the fluid circuit 14. These pressure relief valves 68 and 70 serve as overload protection.

In an alternative exemplary embodiment, the overload protection function can also be implemented integrally on control valves which are already present instead of by means of the additional pressure limiting valves 68 and 70 by mechanical and / or electronic measures.

The operation of the vehicle brake system 10 during service braking, i.e. when braking the vehicle while driving, is described in detail in the aforementioned DE 101 10 658 Cl and is therefore not explained again in detail here. The content of DE 101 10 658 Cl is to be included in this disclosure by reference to it.

The mode of operation of the vehicle brake system according to the invention and the sequence of the method according to the invention when the parking brake function is activated are described below with reference to FIG. 2.

First, the system is started in step S1, for example by the driver pressing the brake pedal in accordance with step S2 and pressing a parking brake button in the vehicle interior in accordance with step S3. When the brake pedal is actuated, a fluid pressure is built up in the fluid circuits 12 and 14 via the brake force generator comprising the master brake cylinder 16 and the brake booster 26. This fluid pressure is detected by means of the pressure sensor 66 in the fluid circuit 14 and by means of a corresponding pressure sensor, not shown, in the fluid circuit 12, as indicated in step S4, and stored in an electronic control unit, not shown. In step S5 it is then checked whether all starting conditions are fulfilled, for example whether the brake pedal has been actuated by the driver, whether the car is at a standstill or / and whether the shift lever of a vehicle equipped with an automatic transmission is in the “parking” position. If the starting conditions are met, control parameters are subsequently loaded in step S6 from the electronic control unit (not shown in FIG. 1), such as the current inclination of the vehicle, the total vehicle weight, the speed at the individual wheels, the current deflection of the brake pedal, the lateral acceleration of the vehicle, the yaw rate or the like. These control parameters are recorded by further sensors, not shown in FIG. 1. On the basis of this information, parameters for controlling the control valves 60 and 62 are calculated, for example the pulse width of a pulse width modulation method with which the control valves 60 and 62 are controlled. In step S7, the

Control valves 60 and 62 are closed using the calculated pulse width in accordance with the pulse width modulation method. Control valves 58 and 64 are also closed.

The pump device 52 is then activated in accordance with step S8. With the activation of the pump device 52, the inlet valves 38 and 40 of the brake units 30 and 32 assigned to the front wheels are closed in step S9 with the aid of the pulse-width modulation method with a holding force which corresponds to the fluid pressure at the start of the activation of the parking brake function.

In step S10, it is monitored whether the driver further increases the fluid pressure in the fluid circuits 12 and 14 by pressing the brake pedal harder or again. Such an increase in pressure would take place, for example, if the driver wanted to park the vehicle on an inclined road by depressing the brake pedal to a certain extent and noting that the vehicle had not yet come to a complete standstill despite the brake pedal already being depressed. In such a situation, the driver will depress the brake pedal more, so that the vehicle stops safely on the inclined road.

If it is recognized in step S10 that the fluid pressure is further increased by the driver, then an additional amount of brake fluid is delivered from the master brake cylinder 16 into the brake units 28, 30, 32 and 34 and then into the fluid reservoirs 54 and 56, the pulse width of the Inlet valves 38 and 40 of the brake units 30 and 32 assigned to the front wheels are adapted to the current fluid pressure.

If no further pressure increase is detected in step S10, the system proceeds to the next step S11. In this step, the exhaust valves 46 and 48 of the brake units 30 and 32 assigned to the front wheels opened and brake fluid drained into the fluid reservoirs 54 and 64.

In step S12, taking into account the other control parameters loaded in step S6, the electronic control unit calculates whether the brake fluid volume stored in the fluid stores 54 and 56 is sufficient to build up a sufficiently high fluid pressure in the brake units 28 and 34 so that a reliable parking brake effect is ensured ,

As a result, the inlet valves 36 and 42 of the brake units 28 and 34 assigned to the rear wheels are opened and the inlet valves 36 and 42 of the brake units 30 and 32 assigned to the front wheels are closed. Furthermore, the outlet valves 44 and 50 of the brake units 28 and 34 assigned to the rear wheels are closed and the outlet valves 46 and 48 of the brake units 30 and 32 assigned to the front wheels are opened to discharge brake fluid into the fluid reservoirs 54 and 56. With this position of the intake valves 36, 38, 40, 42 and the exhaust valves 44, 46, 48, 50, and with the control valves 58, 60, 62 and 64 in the closed position at the same time, the pump device 52 delivers brake fluid from the ones assigned to the front wheels in step S13 Brake units 30 and 32 to the brake units 28 and 34 assigned to the rear wheels, so that a fluid pressure builds up in the latter, which leads to a sufficient tightening of the brake units 28 and 34.

In step S14, the system checks whether the brake fluid diverted from the brake units 30 and 32 of the front axle into the brake units 28 and 34 of the rear axle is sufficient to achieve a reliable parking brake effect. If it turns out that this is not the case, the system jumps back to step S8 and further brake fluid is delivered from the master brake cylinder 16 into the fluid reservoirs 54 and 56. If, on the other hand, step S14 shows that the brake fluid volume stored in the fluid stores 54 and 56 is sufficient to activate a reliable parking brake function, the brake units 28 and 34 are blocked in step S15 in a customary manner, for example by respectively blocking a mechanical parking brake arrangement. The parking brake function is now activated so that the vehicle is safely parked in step S16.

To deactivate the parking brake function, the brake pedal only has to be depressed sufficiently again or it can be one of the preceding ones described methods for activating the parking brake function analog algorithm can be started. In both cases, the mechanical parking brake arrangement of the brake units 28 and 34 is released. The vehicle brake system is then again in a state in which normal service braking can be carried out.

The invention described above makes it possible to utilize a fluidically actuated vehicle brake system to activate a parking brake function, the activation of the pump device required for this in the interior of the vehicle not leading to disruptive noises and also not being felt by the driver through an unusual relenting of the brake pedal.

Claims

claims

1. Method for braking a vehicle by means of a fluidically controllable vehicle brake system (10), the vehicle brake system (10) in each case one

Has a fluidically controllable brake unit (28, 30, 32, 34) assigned to the vehicle wheel, which is fluidically coupled to a braking force generator (16, 26) via at least one fluid circuit (12, 14), one in the at least one fluid circuit (12, 14) Pump device (52) for conveying brake fluid is provided, by means of which at least one of the brake units (28, 30, 32, 34) can be charged with brake fluid, regardless of an activation of the brake force generator (16, 26), and wherein in the fluid circuit (12, 14) control valves (58, 60, 62, 64) are provided, by means of which the braking force generator (16, 26) can be fluidically coupled to and decoupled from the braking units (28, 30, 32, 34) and the pump device (52), characterized in that the following steps are carried out to bring about a parking brake condition;

A) building up a fluid pressure via the braking force generator (16, 26) in the at least one fluid circuit (12, 14), so that at least two of the braking units (28, 30, 32, 37) are controlled fluidically; B) decoupling the braking force generator (16, 26) from the braking units (28, 30, 32, 34) and the pump device (52) by closing the control valves (58, 60, 62, 64); C) activating the pump device (52) and delivering brake fluid from one of the at least two brake units (30, 32) to the other of the at least two brake units (28, 34).

2. The method according to claim 1, characterized in that the pump device (52) is controlled in accordance with certain parameters, for example the vehicle inclination and / and the vehicle weight or / and the wheel speed or / and the operating position of a parking brake switch and / or the brake pedal actuation or / and the yaw rate or / and the lateral acceleration or / and the fluid pressure generated by the braking force generator.

3. The method according to claim 1 or 2, characterized in that each of the fluid circuits (12, 14) is assigned at least one fluid reservoir (54, 56).

4. The method according to claim 3, characterized in that brake fluid is temporarily stored in the fluid reservoir (54, 56) and is conveyed in step C) by the pump device (52) to the respective other brake unit (28, 34).

5. The method according to claim 3 or 4, characterized in that when the fluid pressure is increased by the braking force generator (16, 26) during step B), the control valves (58, 60, 62, 64) are activated in such a way that additional brake fluid from the braking force generator (16, 26) is stored in the fluid reservoir (54, 56) and then the braking force generator (16, 26) from the braking units (28, 30, 32, 34) and the pump device (52) by closing the control valves (58 , 60,62,64) is decoupled.

6. The method according to any one of the preceding claims, characterized in that the control valves (58, 60, 62, 64) are activated according to a pulse method, for example a pulse width modulation method.

7. The method according to any one of the preceding claims, characterized in that the pump unit (52) as a return pump in the fluid circuit (12, 14), in particular as part of an electronic control system, for example an electronic stability system and / or an anti-lock system and / or a traction control system and / or an automatic speed control system.

8. The method according to any one of the preceding claims, characterized in that two fluid circuits (12, 14) are provided, each fluid circuit (12, 14) each having a brake unit (30, 32) assigned to a front wheel and a brake unit assigned to a rear wheel (28,34) is fluidly coupled.

9. The method according to any one of the preceding claims, characterized in that the vehicle wheels respectively assigned to a fluid circuit (12, 14) are arranged diagonally on the vehicle.

10. The method according to any one of the preceding claims, characterized in that in step C) brake fluid is conveyed from the front wheel to the rear wheel.

11. Vehicle brake system (10), each with a fluidically controllable brake unit (28, 30, 32, 34) assigned to a vehicle wheel, which is fluidically coupled to at least one fluid circuit (12, 14) with a brake force generator (16, 26), in which At least one fluid circuit (12, 14) is provided with a pump device (52) for conveying brake fluid, by means of which at least one of the brake units is independent of an activation of the brake force generator (16, 26)

(28, 30, 32, 34) can be filled with brake fluid, and wherein in the fluid circuit (12, 14) control valves (58, 60, 62, 64) are provided, by means of which the brake force generator (16, 26) with the brake units ( 28, 30, 32, 34) and the pump device (52) can be fluidly coupled and uncoupled from them, characterized in that, in order to bring about a parking brake state, the braking force generator (16, 26) builds up a fluid pressure in the at least one fluid circuit (12, 14) in order to fluidly control at least two of the brake units (28, 30, 32, 34) so that the control valves (58, 60, 62, 64) can also be controlled such that the braking force generator (16, 26) is actuated by the brake units (28, 30 , 32, 34) and the pump device (52) is fluidically decoupled and that after the fluidic decoupling of the braking force generator (16, 26) the pump device (52) brake fluid from one of the at least two braking units (30, 32) to the other of the at least one promotes two brake units (28,34).

12. Vehicle brake system according to claim 11, characterized by sensors for determining the vehicle inclination and / and the vehicle weight or / and the wheel speed or / and an operating position of a parking brake switch and / and the current deflection of a brake pedal and / and the lateral acceleration of the yaw rate of the vehicle or / and the fluid pressure generated by the braking force generator.

13. Vehicle brake system according to claim 11 or 12, characterized in that each of the fluid circuits (12, 14) is assigned at least one fluid reservoir (54, 56).

14. Vehicle brake system according to one of claims 11 to 13, characterized in that the control valves (58, 60, 62, 64) can be controlled by a pulse width modulation method.

15. Vehicle brake system according to one of claims 11 to 14, characterized in that the pump unit (52) as a return pump in the fluid circuit (12, 14), in particular as part of an electronic control system, for example an electronic stability system and / or an anti-lock system or / and a traction control system or / and an automatic speed control system.

16. Vehicle brake system according to one of claims 11 to 15, characterized in that two fluid circuits (12, 14) are provided, each fluid circuit (12, 14) each having a brake unit (30, 32) assigned to a front wheel and a rear wheel assigned brake unit (28,34) is fluidly coupled.

17. Vehicle brake system according to one of claims 11 to 16, characterized in that the vehicle wheels respectively assigned to a fluid circuit (12, 14) are arranged diagonally on the vehicle.

18. Vehicle brake system according to one of claims 11 to 17, characterized in that the individual brake units (28, 30, 32, 34) can be charged with brake fluid via inlet valves (36, 38, 40, 42), the inlet valves (36 , 38, 40, 42) can be controlled by a pulse width modulation method.