Rotational damper for a motor vehicle

What is claimed is: 1 .- 9 . (canceled) 10 . A rotational damper for a motor vehicle, comprising: a gyro element, said gyro element comprising a first shaft, supported for rotation relative to a first component and connected with a second component, which performs a relative movement relative to the first component, said first shaft having a first frame, a second shaft rotatably supported in the first frame and arranged orthogonal to the first shaft, said second shaft having a second frame, and a third shaft rotatably supported in the second frame and arranged orthogonal to the second shaft, said third shaft having an inertia weight, said second shaft and said third shaft, said second shaft being connected with a first shaft drive, said third shaft being connected with a second shaft drive, wherein a rotation of the second shaft by the second shaft drive causes a change of an angular velocity or a change of a moment of the first shaft; a first sensor for determining a rotation of the first shaft; a control unit operatively connected with the second shaft drive for adjusting an angular velocity and/or a moment of the second shaft; and a second sensor connected with the controller and adapted for determining a change in position of the first component. 11 . The rotational damper arrangement of claim 10 , wherein the control unit is connected with the second shaft drive so that the second shaft drive is capable of increasing the angular velocity and/or the moment of the second shaft. 12 . The rotational damper arrangement of claim 10 , wherein the first sensor is adapted for measuring an angular velocity or a moment of the first shaft and is connected with the control unit, said control unit controlling the angular velocity or the moment of the first shaft by using the angular velocity or the torque measured by the first sensor as control value. 13 . The rotational damper arrangement of claim 10 , wherein the control unit controls the second shaft by introducing energy into or withdrawing energy from the second shaft drive by using the moment of the second shaft as manipulated variable. 14 . The rotational damper arrangement of claim 10 , further comprising detection devices, which detect an angular position of the first shaft and the second shaft as input variable for the control unit. 15 . The rotational damper arrangement of claim 10 , wherein a transmission ratio between individual torques of the first, second and third shafts is a function of a rotational inertia of the inertia weight. 16 . A method for controlling a rotational damper arrangement, comprising: providing the rotational damper arrangement of claim 10 ; controlling the torque of the first shaft and/or the angular velocity of the first shaft as control variable; and influencing a manipulated variable of the second shaft so that a sign of an acceleration of the third shaft corresponds to a sign of an angular velocity of the third shaft. 17 . The method of claim 16 , further comprising storing a damper characteristic curve of the moment of the first shaft as a function of the angular velocity of the first shaft, wherein a set value for controlling the control variable is dependent on the measured angular velocity of the first shaft. 18 . A cardanically supported gyro element for damping a movement of a first component of a motor vehicle relative to a second component of the motor vehicle, said gyro element comprising: a first shaft, supported for rotation relative to the first component and connected with the first component, said first shaft having a first frame, a second shaft rotatably supported in the first frame and arranged orthogonal to the first shaft, said second shaft having a second frame, and a third shaft rotatably supported in the second frame and arranged orthogonal to the second shaft, said third shaft having an inertia weight, said second shaft and said third shaft, said second shaft being connected with a first shaft drive, said third shaft being connected with a second shaft drive, wherein a rotation of the second shaft by the second shaft drive causes a change of an angular velocity or a change of a moment of the first shaft, wherein the first component is a sprung mass of the motor vehicle and the second component is an unsprung mass of the motor vehicle;