Actuation system, in particular for a vehicle brake, and method for operating the actuation system

The invention claimed is: 1. An actuation system for a vehicle brake, including: an actuating device, at least one first pressure source, comprising a first piston-cylinder unit, which is arranged to be actuated by means of the actuating device, and a second pressure source, comprising a second piston-cylinder unit, including two working chambers separated by a piston of the second piston-cylinder unit and an electro-mechanical drive, wherein the first and second pressure sources are each connected to at least one brake circuit via a hydraulic line, in order to supply the brake circuit with pressurising medium and to pressurise the vehicle brake, and further including a valve device arranged to regulate brake pressure, wherein during forward and return strokes of the second piston-cylinder unit, at least one brake circuit is enabled to be fed controlled pressurising medium for pressure build-up by way of the second piston cylinder unit, and wherein either the forward stroke and return stroke or the respective working chambers of the second piston-cylinder unit are each assigned to one respective brake circuit for a two-circuit pressure supply. 2. The actuation system according to claim 1 , wherein respective brake circuits are each connected to a working chamber of the first piston-cylinder unit, without intermediary separating valves, and are separated from one another using a piston of an additional piston-cylinder unit. 3. The actuation system according to claim 1 , wherein a first brake circuit is connected to a working chamber on a front side of the first pressure source, and a rear side of the second piston-cylinder unit, and/or wherein a second brake circuit is connected to a working chamber on a front side of the second piston-cylinder unit and a rear side of the first pressure source. 4. The actuation system according to claim 1 , further including a solenoid valve arranged for variable pre-filling of a brake circuit. 5. The actuation system according to claim 4 , further including a closing spring of the solenoid valve, wherein the closing spring is designed for a blocking pressure of the vehicle brake. 6. The actuation system according to claim 1 , further including a pressure reduction valve associated with the second piston-cylinder unit, wherein the pressure reduction valve is open during the forward stroke of a piston of the second piston-cylinder unit. 7. The actuation system according to claim 1 , further including a pressure reduction valve associated with the second piston-cylinder unit, wherein the pressure reduction valve is open during the return stroke of a piston of the second piston cylinder unit. 8. The actuation system according to claim 1 , wherein a multiplex mode occurs by means of a valve circuit. 9. The actuation system according to claim 8 , wherein the actuation system for multiplex mode has at least one pressure reduction valve associated with the second piston-cylinder unit. 10. The actuation system according to claim 8 , wherein the actuation system for multiplex mode comprises a magnetic valve arranged in a hydraulic line between the first pressure source and a reservoir. 11. The actuation system according to claim 1 , wherein the second piston-cylinder unit is used for diagnostic purposes. 12. The actuation system according to claim 11 , characterised in that a suction-valve-throttle combination is arranged for pressure compensation of a third pressure source, comprising piston-cylinder unit having an auxiliary piston, or of a flow control valve in the case of an auxiliary piston with an expansion port. 13. The actuation system according to claim 1 , further including a magnetic valve associated with the second piston-cylinder unit and arranged to feed volume into at least one brake circuit during the return stroke of a piston of the second piston-cylinder unit. 14. The actuation system according to claim 1 , further including at least one sensor arranged for controlling the position of or diagnosing a piston of the first piston-cylinder unit. 15. The actuation system according to claim 1 , further including a path simulator device, without a path simulator piston, and arranged such that a pressure-proportional restoring force acts on the brake pedal, via a tappet. 16. The actuation system according to claim 1 , wherein different effective piston surfaces are enabled to be switched on by means of a corresponding valve circuit during forward stroke and return stroke of the second piston-cylinder unit with and without pre-filling. 17. The actuation system according to claim 16 , wherein greatly different large and small effective piston surfaces are used in forward stroke with and without pre-filling and return stroke for volume delivery with the piston of the second piston-cylinder unit, wherein the large effective piston surface is used for pre-filling, and wherein the effective piston surfaces can be switched over at least during the forward stroke. 18. The actuation system according to claim 16 , wherein the piston surfaces of the double-stroke piston and strokes of the pre-filling and residual stroke are selected in such a way that a volume corresponding to a blocking pressure is achieved during the forward stroke. 19. The actuation system according to claim 1 , further including a solenoid valve arranged in a hydraulic line from one working chamber of the first pressure source to a reservoir, wherein the solenoid valve is configured to cut off a return line to the reservoir when a floating piston is on stop or a seal of the floating piston fails. 20. The actuation system according to claim 1 , wherein pressure build-up and pressure reduction control occurs via the double-stroke piston via pressure volume control. 21. The actuation system according to claim 1 , wherein, per wheel brake, either an inlet valve and an outlet valve or only one valve is disposed, wherein either at least one of the inlet and outlet valves or the only one valve is opened for pressure build-up and pressure reduction in a respective wheel brake. 22. A method for operating the actuation system according to claim 1 , the method including: changing a pressure in at least one brake circuit by means of a double-stroke piston of the second piston-cylinder unit, wherein said changing the pressure is separated in two brake circuits by means of a piston of the first piston-cylinder unit by movement of the double-stroke piston of the second piston-cylinder unit. 23. The method according to claim 22 , further including: supplying pressure medium to a first brake circuit during a forward stroke of the double-stroke piston of the second piston-cylinder unit for pressure build-up, and also supplying pressure medium to another brake circuit via the piston of the first piston-cylinder unit, supplying pressure medium to the another brake circuit on the return stroke, and also supplying pressure medium to the first brake circuit via the piston of the first piston-cylinder unit; and/or reducing pressure in at least one brake circuit or at least one wheel brake by means of the second piston-cylinder unit, either only during the forward stroke or during both the forward stroke and return stroke of the double-stroke piston of the second piston-cylinder unit. 24. The method according to claim 23 , further including connecting a circuit of the forward or return stroke to a different brake circuit when the double-stroke piston is being fed