Actuator device and method for operating an actuator device

The invention claimed is: 1. An actuator device having at least one actuator element, which consists at least partially of a magnetically shape-shiftable material and which is configured at least for a purpose of causing a movement of at least one actuation element in at least one direction of movement by means of a contraction, and having a magnetic contraction unit, which is configured for the purpose of supplying a magnetic field acting upon the at least one actuator element in order to generate a contraction of the at least one actuator element in the longitudinal direction of extent of the at least one actuator element, wherein, in a region of the at least one actuator element, field lines of the magnetic field are aligned at least substantially parallel to the at least one direction of movement, wherein the magnetically shape-shiftable material is a magnetic shape-memory alloy which contains nickel, manganese, and gallium, wherein the magnetic contraction unit comprises a coil unit that surrounds the at least one actuator element at least partially, which is configured for the purpose of generating a magnetic field acting on the at least one actuator element in at least one operating state and thereby causing the contraction of the at least one actuator element, wherein the magnetic contraction unit has two flux concentrators, which are configured for the purpose of intensifying the magnetic field acting on the at least one actuator element, wherein the two flux concentrators are arranged in opposing axial end regions of the at least one actuator element, and wherein the flux concentrators do not form a fully closed magnetic circuit. 2. The actuator device as claimed in claim 1 , wherein the at least one actuator element is configured at least for a purpose of transmitting a tensile force onto the at least one actuation element. 3. The actuator device as claimed in claim 1 , wherein the magnetic field causes a change in a length of the at least one actuator element in the at least one direction of movement of at least 2%. 4. The actuator device as claimed in claim 1 , comprising the at least one actuation element, to which the at least one actuator element is rigidly connected. 5. The actuator device as claimed in claim 1 , wherein the magnetic contraction unit for supplying the magnetic field comprises at least one magnet element embodied as an air-core coil. 6. The actuator device as claimed in claim 1 , wherein the magnetic contraction unit for supplying the magnetic field comprises at least one magnet element embodied as a ribbon coil. 7. The actuator device as claimed in claim 1 , wherein the magnetic contraction unit for supplying the magnetic field comprises at least one magnet element consisting of stacked disk springs. 8. The actuator device as claimed in claim 1 , comprising a detection unit, which is configured for a detection of at least one actuation parameter that is correlated with the movement of the at least one actuation element, wherein the at least one actuation parameter is an induction voltage caused by a deformation of the at least one actuator element and/or an induction current caused by a deformation of the at least one actuator element. 9. A method for operating the actuator device, in particular as claimed in claim 1 , which has at least one actuator element, which consists at least partially of a magnetically shape-shiftable material, wherein the at least one actuator element is contracted by means of a magnetic field acting on the at least one actuator element and a movement of at least one actuation element in at least one direction of movement is caused by means of the contraction of the at least one actuator element, wherein, in the longitudinal direction of extent of the at least one actuator element, and in the region of the at least one actuator element, field lines of the magnetic field are aligned at least substantially parallel to the at least one direction of movement. 10. The actuator device as claimed in claim 1 , wherein the magnetically shape-shiftable material is of monocrystalline configuration. 11. The actuator device as claimed in claim 10 , wherein the magnetically shape-shiftable material has a tetragonal crystal structure with lattice constants a, b=a and c, wherein c/a<1, and the magnetically shape-shiftable material has a magnetic anisotropy, and wherein a magnetic permeability is greater in a direction of a c-axis than along an a-axis and a b-axis. 12. The actuator device as claimed in claim 1 , wherein the magnetic contraction unit has at least one flux concentrator, which is configured for a purpose of intensifying the magnetic field acting on the at least one actuator element. 13. The actuator device as claimed in claim 12 , wherein the at least one flux concentrator is arranged in an axial end region of the at least one actuator element. 14. The actuator device as claimed in claim 1 , comprising an expansion unit, which is configured for an expansion of the at least one actuator element. 15. The actuator device as claimed in claim 14 , wherein the expansion unit comprises at least one expansion element that is embodied as an elastic element, in particular a spring element. 16. The actuator device as claimed in claim 14 , wherein the expansion unit comprises at least one expansion element that is embodied as a permanent magnet. 17. A valve, in particular a pneumatic valve, having at least one actuator, which has the actuator device as claimed in claim 1 . 18. A valve system having a valve block and a plurality of valves as claimed in claim 17 arranged in the valve block, wherein the plurality of valves have a minimum distance, in particular a grid dimension, of at most 10 mm, preferably of at most 7 mm.