Sensor for a nuclear magnetic resonance device

The invention claimed is: 1. A sensor for a nuclear magnetic resonance device for determining at least one material property of a material sample arranged in a useful volume comprising: a magnetic field generation apparatus having a planar magnet arrangement configured to generate a static magnetic field in the useful volume, wherein the planar magnet arrangement has a plurality of magnetic poles on a front side facing the useful volume, and wherein the magnetic poles are arranged adjacently to each other along a first extension direction of the planar magnet arrangement with a respectively alternating orientation; and a measuring apparatus configured to measure a signal based on a nuclear magnetic resonance of the material sample arranged in the useful volume, the measuring apparatus including an electrical coil having at least one winding configured to generate an alternating magnetic field in the useful volume, wherein the at least one winding is arranged between two directly adjacent magnetic poles of the plurality of magnetic poles, such that the alternating magnetic field of the electrical coil is superimposed substantially orthogonally with the static magnetic field of the planar magnet arrangement in the entire useful volume, wherein the electrical coil is configured in the form of a multiresonant coil. 2. The sensor as claimed in claim 1 , wherein: the planar magnet arrangement comprises a plurality of magnet segments, which are arranged adjacently to one another and which respectively have directions of magnetization which are oriented orthogonally to a second extension direction of the planar magnet arrangement orthogonal to the first extension direction; and each magnet segment of the plurality of magnet segments which is arranged directly adjacently to another one of the plurality of magnet segments along the first extension direction of the planar magnet arrangement has a direction of magnetization which is rotated relative to the other one of the plurality of magnet segments, such that the static magnetic field is generated predominantly on the front side of the planar magnet arrangement compared to a reverse side of the planar magnet arrangement. 3. The sensor as claimed in claim 2 , the magnetic field generation apparatus further comprising: a carrier plate of a non-magnetic material, wherein the magnet segments are fitted into at least one opening in the carrier plate, wherein at least a portion of the magnet segments of the magnet arrangement are rotatably fitted within the carrier plate. 4. The sensor as claimed in claim 3 , wherein the magnetic field generation apparatus is extendable in a modular manner by the side-by-side arrangement of a plurality of carrier plates in at least one of the first extension direction and the second extension direction of the planar magnet arrangement. 5. The sensor as claimed in claim 2 , wherein: a first plurality of the magnet segments in an edge region of the planar magnet arrangement are configured to generate a portion of the static magnetic field with a higher magnetic field strength than a portion of the static magnetic field generated by a second plurality of the magnet segments in a central region of the planar magnet arrangement; the first plurality of magnet segments have a first magnetization and a first vertical extension; the second plurality of magnet segments in the central region of the planar magnet arrangement have a second magnetization and a second vertical extension; and at least one of the first magnetization and the first vertical extension is greater than the second magnetization or the second vertical extension. 6. The sensor as claimed in claim 5 , wherein, the first plurality of magnet segments are arranged one on top of another to achieve the portion of the static magnetic field with the higher magnetic field strength. 7. The sensor as claimed in claim 2 , wherein at least a portion of the magnet segments in the planar magnet arrangement comprises a jacket made from a plastic. 8. The sensor as claimed in claim 1 , wherein; along the first extension direction of the planar magnet arrangement, each magnet segment of the plurality of magnet segments which is arranged directly adjacently to another one of the plurality of magnet segments has a direction of magnetization which is rotated 45° in relation to the other one of the plurality of magnet segments. 9. The sensor as claimed in claim 1 , wherein the electrical coil is further configured to measure a signal which is based on the nuclear magnetic resonance of the material sample which is arranged in the useful volume. 10. The sensor as claimed in claim 1 , wherein the electrical coil is arranged on the front side of the planar magnet arrangement. 11. The sensor as claimed in claim 1 , wherein: the electrical coil is configured in the form of a structured electrically conductive layer; and in the electrically conductive layer, at least one shim coil is further configured to homogenize the static magnetic field which is generated by the planar magnet arrangement in the useful volume. 12. The sensor as claimed in claim 1 , wherein: four magnetic poles having respectively alternating orientations are configured on the front side of the planar magnet arrangement; and the electrical coil of the measuring apparatus comprises three adjacently arranged windings, each of the three adjacently arranged windings having a respective magnetic pole arranged between two directly adjacent magnetic poles of the planar magnet arrangement. 13. The sensor as claimed in claim 1 , further comprising: an inner shielding structure of an electrically conductive material having a high magnetic permeability arranged between the electrical coil and the planar magnet arrangement, the inner shielding structure configured to shield the magnet segments from the alternating magnetic field of the electrical coil. 14. The sensor as claimed in claim 1 , further comprising: an outer shielding structure of an electrically conductive material having a high magnetic permeability arranged between the electrical coil and the useful volume, the outer shielding structure configured to shield the electrical coil from electromagnetic interference fields, and including a plurality of resonance structures, the plurality of resonance structures configured to shield, in a targeted manner, electromagnetic interference fields with frequencies in a region of a network frequency. 15. A nuclear magnetic resonance device comprising a sensor as claimed in claim 1 , wherein the nuclear magnetic resonance device is configured to determine at least one material property of the material sample for each of a plurality of measuring layers in the useful volume. 16. The nuclear magnetic resonance device as claimed in claim 15 , wherein the nuclear magnetic resonance device comprises; a lifting device having at least one electrically- and/or manually-driven actuator configured to set a distance between the sensor and the material sample. 17. The nuclear magnetic resonance device as claimed in claim 16 , wherein the actuator comprises: a first actuator part configured to carry the sensor; and a second actuator part moveable with respect to the sensor and having a contact surface configured to engage a surface which is arranged in a stationary manner in relation to the material sample. 18. The nuclear magnetic resonance device as claimed in claim 17 , wherein: the first actuator part is configured in the form of an electric motor; and the second actuator part is c