Mechanical combustion-engine-driven fluid pump with a magneto-rheological multi-disk clutch

What is claimed is: 1. A mechanical combustion-engine-driven fluid pump comprising: an input shaft configured to be directly driven by a combustion engine; a pumping unit comprising a pump rotor; and a magneto-rheological multi-disk clutch arranged between the input shaft and the pump rotor, the magneto-rheological multi-disk clutch comprising, at least two radial input clutch disks, at least two radial output clutch disks, the at least two radial input clutch disks and the at least two radial output clutch discs together defining at least two radial clutch liquid gaps arranged between the at least two radial input clutch disks and the at least two radial output clutch discs, the at least two radial clutch liquid gaps being filled with a magneto-rheological clutch liquid, a permanent magnet element configured to be shiftable between an engaged position wherein a magnetic field of the permanent magnet element penetrates the at least two radial clutch liquid gaps with a high magnetic flux, and a disengaged position wherein the magnetic field of the permanent magnet element is less than in the engaged position, an actuator configured to move the permanent magnet element between the engaged position and the disengaged position, and a magnet chamber arranged radially inwardly of the at least two radial input clutch disks and the at least two radial output clutch discs, wherein the permanent magnet element is arranged in the magnet chamber so as to move between the engaged position and the disengaged position, wherein, the permanent magnet element is arranged so as to be shiftable in an axial direction, the magnet chamber comprises a first magnet chamber wall which comprises a longitudinal engagement section made of a non-ferromagnetic material, the longitudinal engagement section being configured to intersect with the radial planes of the at least two radial clutch liquid gaps, and magnet chamber comprises a second magnet chamber wall which comprises a longitudinal disengagement section made of a ferromagnetic material so as to shield the magnetic field of the permanent magnet element with respect to the at least two radial clutch liquid gaps in the disengaged position of the permanent magnet element. 2. The mechanical combustion-engine-driven fluid pump as recited in claim 1 , further comprising a passive pretension element configured to pretension the permanent magnet element into the engaged position. 3. The mechanical combustion-engine-driven fluid pump as recited in claim 1 , wherein the at least two radial clutch liquid gaps comprise radial planes which intersect with the permanent magnet element in the engaged position. 4. The mechanical combustion-engine-driven fluid pump as recited in claim 1 , wherein the actuator is a vacuum actuator. 5. A mechanical combustion-engine-driven fluid pump comprising: an input shaft configured to be directly driven by a combustion engine; a pumping unit comprising a pump rotor; and a magneto-rheological multi-disk clutch arranged between the input shaft and the pump rotor, the magneto-rheological multi-disk clutch comprising, at least two radial input clutch disks, at least two radial output clutch disks, the at least two radial input clutch disks and the at least two radial output clutch discs together defining at least two radial clutch liquid gaps arranged between the at least two radial input clutch disks and the at least two radial output clutch discs, the at least two radial clutch liquid gaps being filled with a magneto-rheological clutch liquid, a permanent magnet element configured to be shiftable between an engaged position wherein a magnetic field of the permanent magnet element penetrates the at least two radial clutch liquid gaps with a high magnetic flux, and a disengaged position wherein the magnetic field of the permanent magnet element is less than in the engaged position, an actuator configured to move the permanent magnet element between the engaged position and the disengaged position, and a magnet chamber arranged radially inwardly of the at least two radial input clutch disks and the at least two radial output clutch discs, wherein the permanent magnet element is arranged in the magnet chamber so as to move between the engaged position and the disengaged position, wherein, the permanent magnet element is arranged so as to be shiftable in an axial direction, and the at least two radial clutch liquid gaps comprise radial planes which intersect with the permanent magnet element in the engaged position. 6. The mechanical combustion-engine-driven fluid pump as recited in claim 5 , further comprising a passive pretension element configured to pretension the permanent magnet element into the engaged position. 7. The mechanical combustion-engine-driven fluid pump as recited in claim 5 , wherein the magnet chamber comprises a first magnet chamber wall which comprises a longitudinal engagement section made of a non-ferromagnetic material, the longitudinal engagement section being configured to intersect with the radial planes of the at least two radial clutch liquid gaps. 8. The mechanical combustion-engine-driven fluid pump as recited in claim 5 , wherein the magnet chamber comprises a second magnet chamber wall which comprises a longitudinal disengagement section made of a ferromagnetic material so as to shield the magnetic field of the permanent magnet element with respect to the at least two radial clutch liquid gaps in the disengaged position of the permanent magnet element. 9. The mechanical combustion-engine-driven fluid pump as recited in claim 5 , wherein the actuator is a vacuum actuator.