Power-assisted braking system for a vehicle and method for controlling the power-assisted braking system

What is claimed is: 1. A power-assisted braking system for a vehicle, comprising: a brake master cylinder having a chamber, which is hydraulically connected to a wheel brake cylinder for braking a wheel of the vehicle; a hydraulic actuator which activates a piston of the brake master cylinder to pressurize hydraulic fluid in the chamber, wherein the hydraulic actuator is a brake booster, which boosts a force mechanically exerted by the driver on the piston of the brake master cylinder; a pressure accumulator, which stores hydraulic fluid under pressure and supplies it to the actuator for activating the piston of the brake master cylinder; a pump which supplies hydraulic fluid to the pressure accumulator from a tank; and a drive device which drives the pump; wherein the pressure side of the pump is hydraulically connected to a first control valve and the pressure accumulator, and the first control valve is further hydraulically connected to the actuator, wherein the tank is hydraulically connected to the actuator with the aid of a second control valve, and a control unit is provided which opens the first control valve to generate a braking torque to supply the actuator with hydraulic fluid and simultaneously controls the second control valve for smoothing the pressure fluctuations occurring during the operation of the pump; wherein the pressure accumulator stores a maximum pressure, which is lower than the pressure needed at the hydraulic actuator for fully decelerating the vehicle, and has a maximum hydraulic volume, which is smaller than the volume needed for completely filling the hydraulic actuator; and wherein the drive device is an electric motor configured to drive the pump for supplying hydraulic fluid to the actuator during a braking period, and the pump fills the pressure accumulator during an overrun of the electric motor following the braking period, wherein the wheel brake cylinder is connected to the chamber via another pump, wherein in an antilock mode, the another pump pumps the hydraulic fluid into the chamber, and wherein the pump and the another pump are both operated by the electric motor. 2. The braking system as recited in claim 1 , wherein the pressure accumulator stores a pressure, which is 5% to 30% lower than the pressure needed at the actuator for fully decelerating the vehicle, and contains a maximum hydraulic volume which is 5% to 30% smaller than the volume needed for completely filling the actuator. 3. The braking system as recited in claim 1 , wherein the pump fills the pressure accumulator during a braking system function test period. 4. The braking system as recited in claim 1 , wherein the control unit controls at least one of the first control valve, the second control valve, and the drive device of the pump for generating a maximum braking torque so that, at the end of the pressure build-up phase, the pump generates most of the hydraulic fluid pressure at the actuator. 5. The braking system as recited in claim 1 , wherein to generate a maximum braking torque, the control unit controls the first control valve and the pump so that, at the end of a pressure build-up phase, the pump generates a larger portion of the hydraulic fluid pressure present in the chamber, and wherein a smaller portion of the pressure is generated by the pressure accumulator. 6. The braking system as recited in claim 1 , wherein to generate a maximum braking torque, the control unit controls the first control valve and the pump so that, at the end of a pressure build-up phase, the pump generates a larger portion, which is more than 50%, of the hydraulic fluid pressure present in the chamber, and wherein a smaller portion, which is less than 50%, of the pressure is generated by the pressure accumulator. 7. The braking system as recited in claim 1 , wherein to generate a maximum braking torque, the control unit controls the first control valve and the pump so that, at the end of a pressure build-up phase, the pump generates a larger portion, which is more than 70%, of the hydraulic fluid pressure present in the chamber, and wherein a smaller portion, which is less than 30%, of the pressure is generated by the pressure accumulator. 8. The braking system as recited in claim 1 , wherein the pressure accumulator supports the pump, including during starting of the pump when the pump is not yet fully functional, and wherein a main contribution of the pressure build-up comes from the pump and the pressure accumulator only provides a minor contribution of the pressure build-up. 9. A method for controlling a power-assisted braking system for a vehicle, comprising: supplying hydraulic fluid to a pressure accumulator with the aid of a pump; and supplying hydraulic fluid from the pressure accumulator to an actuator, wherein the actuator is a brake booster, which boosts a force mechanically exerted by the driver on the piston of the brake master cylinder, and activating a piston of a brake master cylinder with the aid of the actuator to supply hydraulic fluid to a wheel brake cylinder from a chamber of the brake master cylinder to brake a wheel of the vehicle; wherein the pressure side of the pump is hydraulically connected to a first control valve and the pressure accumulator, and the first control valve is further hydraulically connected to the actuator, wherein a tank is hydraulically connected to the actuator with the aid of a second control valve, and a control unit is provided which opens the first control valve to generate a braking torque to supply the actuator with hydraulic fluid and simultaneously controls the second control valve which for smoothing the pressure fluctuations occurring during the operation of the pump; wherein the pressure accumulator stores a maximum pressure, which is lower than the pressure needed at the hydraulic actuator for fully decelerating the vehicle, and has a maximum hydraulic volume, which is smaller than the volume needed for completely filling the hydraulic actuator; and wherein the drive device is an electric motor configured to drive the pump for supplying hydraulic fluid to the actuator during a braking period, and the pump fills the pressure accumulator during an overrun of the electric motor following the braking period, wherein the wheel brake cylinder is connected to the chamber via another pump, wherein in an antilock mode, the another pump pumps the hydraulic fluid into the chamber, and wherein the pump and the another pump are both operated by the electric motor. 10. The method as recited in claim 9 , wherein to generate a maximum braking torque, the control unit controls the first control valve and the pump so that, at the end of a pressure build-up phase, the pump generates a larger portion of the hydraulic fluid pressure present in the chamber, and wherein a smaller portion of the pressure is generated by the pressure accumulator. 11. The method as recited in claim 9 , wherein to generate a maximum braking torque, the control unit controls the first control valve and the pump so that, at the end of a pressure build-up phase, the pump generates a larger portion, which is more than 50%, of the hydraulic fluid pressure present in the chamber, and wherein a smaller portion, which is less than 50%, of the pressure is generated by the pressure accumulator. 12. The method as recited in claim 9 , wherein to generate a maximum braking torque, the control unit controls the first control valve and the pump so that, at the end of a pressure build-up phase, the pump generates a larger portion, which is more than 70%, of the hydraulic fluid pressure present in the chamber, and wherein a smaller portion, which is less than 30%, of the pressure is