Device for reducing rotary vibrations in a drivetrain

What is claimed is: 1. A device for reducing rotary vibrations for a motor vehicle, the motor vehicle comprising: a drive machine; a drivetrain configured to receive torque from the drive machine for transmission of drive power to at least one wheel of the motor vehicle; a primary connector between the drive machine and the drive train configured to receive the torque from the drive machine; a secondary connector between the drive machine and the drive train configured to output the torque from the first connector to the drivetrain; a coupling device between the primary connector and the secondary connector configured to transfer the torque from the drive machine from the primary connector to the secondary connector, the coupling device including a vibration reduction actuator with a coupling piston chamber and a coupling piston displaceably arranged in the coupling piston chamber; a pressure generating device fluidly coupled to the coupling piston chamber by a first fluid line; and a pressure-balancing device fluidly coupled to the pressure-generating device via the first fluid line, wherein the coupling piston is configured to generate a vibration reduction force when loaded with a working pressure in the coupling piston chamber, the coupling piston chamber and the coupling piston are coupled to the primary and the secondary connectors such that a rotational movement of the primary connector relative to the secondary connector causes the coupling piston to be displaced in the coupling piston chamber counter to the vibration reduction force, and the working pressure in the coupling piston chamber is variable in response to pressure generated by the pressure-generating device. 2. The rotary vibration reduction device as claimed in claim 1 , further comprising: a further coupling pressure chamber arranged in the coupling device, wherein the piston chamber and the further piston chamber are separated fluid-tightly from each other by the coupling piston. 3. The rotary vibration reduction device as claimed in claim 2 , wherein the further pressure generating device is fluidly coupled to the further piston chamber such that a working pressure in the further piston chamber is variable in response to pressure generated by the further pressure-generating device. 4. The rotary vibration reduction device as claimed in claim 3 , further comprising: a further pressure-balancing device fluidly coupled to the further pressure-generating device. 5. The rotary vibration reduction device as claimed in claim 4 , further comprising: a decoupling device with a decoupling cylinder having a primary decoupler piston chamber, a secondary decoupler piston chamber, and a decoupler piston arranged in the decoupling cylinder such that the primary and secondary decoupler piston chambers are separated fluid-tightly from each other by the decoupler piston, wherein the pressure-generating device is fluidly connectable to the primary decoupler piston chamber, and the secondary decoupler piston chamber is selectively fluidly connectable to the coupling piston chamber or to the further coupling piston chamber. 6. The rotary vibration reduction device as claimed in claim 5 , wherein the decoupling device has a decoupling actuator configured to vibrate the decoupler piston in contraphase to rotational irregularities between the drive machine and the drivetrain. 7. The rotary vibration reduction device as claimed in claim 4 , wherein at least one of the pressure-generating device and the further pressure-generating device is arranged to rotated with a corresponding one of the primary and secondary connectors. 8. The rotary vibration reduction device as claimed in claim 4 , wherein at least one of the pressure-generating device and the further pressure-generating device is arranged in a stationary manner on a carrier element of a motor vehicle, such that the primary and secondary connectors rotate relative to at least one of the pressure-generating device and the further pressure-generating device arranged on the carrier element. 9. The rotary vibration reduction device as claimed in claim 1 , further comprising: a spring device is arranged between the primary connector and the secondary connector in a torque transmission direction such that a spring force generated by the spring device is transmittable from the primary connector to the secondary connector, wherein the spring force is changed when the primary connector rotates relative to the secondary connector. 10. The rotary vibration reduction device as claimed in claim 9 , wherein the spring device and the vibration reduction actuator are connected mechanically in series. 11. The rotary vibration reduction device as claimed in claim 9 , wherein the spring device and the vibration reduction actuator are connected mechanically in parallel. 12. The rotary vibration reduction device as claimed in claim 1 , wherein the vibration reduction actuator is an energy recuperating actuator. 13. A method for reducing rotary vibrations for a motor vehicle, the motor vehicle including a drive machine, a drivetrain configured to receive torque from the drive machine for transmission of drive power to at least one wheel of the motor vehicle, a primary connector between the drive machine and the drive train configured to receive the torque from the drive machine, a secondary connector between the drive machine and the drive train configured to output the torque from the first connector to the drivetrain, a coupling device between the primary connector and the secondary connector configured to transfer the torque from the drive machine from the primary connector to the secondary connector, the coupling device including a vibration reduction actuator with a coupling piston chamber, a further coupling piston chamber, a coupling piston displaceably fluid-tightly separating the coupling piston chamber from the further coupling piston chamber, the coupling piston chamber and the coupling piston being coupled to the primary and the secondary connectors such that a rotational movement of the primary connector relative to the secondary connector causes the coupling piston to be displaced counter to the vibration reduction force, a pressure generating device fluidly coupled to the coupling piston chamber such that a working pressure in the coupling piston chamber is variable in response to pressure generated by the pressure-generating device, a further pressure generating device fluidly coupled to the further coupling piston chamber such that a working pressure in the further coupling piston chamber is variable in response to pressure generated by the further pressure-generating device, a pressure-balancing device fluidly coupled to the pressure-generating device such that a working pressure in the coupling piston chamber is variable in response to pressure generated by the pressure-generating device, a further pressure-balancing device fluidly coupled to the further pressure-generating device such that a working pressure in the further coupling piston chamber is variable in response to pressure generated by the further pressure-generating device, and a first sensor configured to detect a rotational movement of the primary connector and a second sensor configured to detect a rotational movement of the second connector, wherein the coupling piston is configured to generate a vibration reduction force when loaded with a working pressure in at least one of the coupling piston chamber and the further coupling piston chamber, the method comprising the acts of: detecting a rotational movement of the primary con