Electromagnetically actuatable inlet valve and high-pressure pump having an inlet valve

What is claimed is: 1. An electromagnetically actuable inlet valve ( 24 ) for a high-pressure pump, the inlet valve comprising: a valve member ( 34 ) which is configured to be moved between an open position and a closed position, and having an electromagnetic actuator ( 60 ) by way of which the valve member ( 34 ) is moved, wherein the electromagnetic actuator ( 60 ) has a magnet armature ( 68 ) which is configured to move the valve member ( 34 ), a magnet coil ( 64 ) which surrounds the magnet armature ( 68 ), and a magnet core ( 66 ), wherein the magnetic armature ( 68 ) is configured to be moved toward the magnetic core ( 66 ) when the magnet coil ( 64 ) is energized, wherein the magnet armature ( 68 ) is guided in a displaceable manner in a carrier element ( 78 ), and wherein the carrier element ( 78 ) and the magnet core ( 66 ) are connected to one another, characterized in that the carrier element ( 78 ) and the magnet core ( 66 ) are connected to one another via a sleeve-like connection element ( 90 ), wherein the sleeve-like connection element ( 90 ) is connected to the carrier element ( 78 ) in a materially bonded manner in a first connection region ( 92 ) and in a form-fitting manner in a second connection region ( 94 ) which is offset from the first connection region ( 92 ) in a direction of a longitudinal axis ( 91 ) of the connection element ( 90 ), wherein the connection element ( 90 ) has a preload in the direction of its longitudinal axis ( 91 ) between the first connection region ( 92 ) and the second connection region ( 94 ). 2. The inlet valve as claimed in claim 1 , characterized in that the first connection region ( 92 ) is arranged in an end region, as viewed in the direction of the longitudinal axis ( 91 ), of the connection element ( 90 ), and in that the second connection region ( 94 ) is offset toward a center of the connection element ( 90 ) in relation to the first connection region ( 92 ). 3. The inlet valve as claimed in claim 1 , characterized in that the carrier element ( 78 ) has in an outer casing at least one depression ( 96 ) into which the connection element ( 90 ) enters, while the connection element is plastically deformed, for the purpose of the form-fitting connection. 4. The inlet valve as claimed in claim 3 , characterized in that the at least one depression ( 96 ) is formed as a circumferential bead. 5. The inlet valve as claimed in claim 1 , characterized in that the preload is a tensile preload in the direction of the longitudinal axis ( 91 ) between the first connection region ( 92 ) and the second connection region ( 94 ). 6. The inlet valve as claimed in claim 1 , characterized in that the connection element ( 90 ) is configured to be elastically deformed in the direction of its longitudinal axis ( 91 ) in a section adjacent to the second connection region ( 94 ). 7. The inlet valve as claimed in claim 1 , characterized in that the materially bonded connection of the connection element ( 90 ) to the carrier element ( 78 ) in the first connection region ( 92 ) is a welded connection. 8. A high-pressure pump comprising the inlet valve ( 24 ) as claimed in claim 1 , and at least one pump element ( 10 ) which has a pump piston ( 12 ) that delimits a pump working chamber ( 18 ), wherein the pump working chamber ( 18 ) is configured to be connected to an inflow ( 26 ) via the inlet valve ( 24 ). 9. A method of forming the inlet valve as claimed in claim 1 , the method comprising: welding the connection element ( 90 ) to the carrier element ( 78 ) at the first connection region ( 92 ); and subsequent to welding, applying a tensile force in the direction of the longitudinal axis and then plastically deforming the connection element ( 90 ) into a depression ( 96 ) of the carrier element ( 78 ) at the second connection region ( 94 ), so as to form the preload. 10. An electromagnetically actuable inlet valve ( 24 ) for a high-pressure pump, the inlet valve comprising: a valve member ( 34 ) which is configured to be moved between an open position and a closed position, and having an electromagnetic actuator ( 60 ) by way of which the valve member ( 34 ) is moved, wherein the electromagnetic actuator ( 60 ) has a magnet armature ( 68 ) which is configured to move the valve member ( 34 ), a magnet coil ( 64 ) which surrounds the magnet armature ( 68 ), and a magnet core ( 66 ), wherein the magnetic armature ( 68 ) is configured to be moved toward the magnetic core ( 66 ) when the magnet coil ( 64 ) is energized, wherein the magnet armature ( 68 ) is guided in a displaceable manner in a carrier element ( 78 ), and wherein the carrier element ( 78 ) and the magnet core ( 66 ) are connected to one another, characterized in that the carrier element ( 78 ) and the magnet core ( 66 ) are connected to one another via a sleeve-like connection element ( 90 ), wherein the sleeve-like connection element ( 90 ) is connected to the magnet core ( 66 ) in a materially bonded manner in a first connection region ( 92 ) and in a form-fitting manner in a second connection region ( 94 ) which is offset from the first connection region ( 92 ) in a direction of a longitudinal axis ( 91 ) of the connection element ( 90 ), wherein the connection element ( 90 ) has a preload in the direction of its longitudinal axis ( 91 ) between the first connection region ( 92 ) and the second connection region ( 94 ). 11. The inlet valve as claimed in claim 10 , characterized in that the first connection region ( 92 ) is arranged in an end region, as viewed in the direction of the longitudinal axis ( 91 ), of the connection element ( 90 ), and in that the second connection region ( 94 ) is offset toward a center of the connection element ( 90 ) in relation to the first connection region ( 92 ). 12. The inlet valve as claimed in claim 10 , characterized in that the magnet core ( 66 ) has in an outer casing at least one depression ( 96 ) into which the connection element ( 90 ) enters, while the connection element is plastically deformed, for the purpose of the form-fitting connection. 13. The inlet valve as claimed in claim 12 , characterized in that the at least one depression ( 96 ) is formed as a circumferential bead. 14. The inlet valve as claimed in claim 10 , characterized in that the connection element ( 90 ) is configured to be elastically deformed in the direction of its longitudinal axis ( 91 ) in a section adjacent to the second connection region ( 94 ). 15. The inlet valve as claimed in claim 10 , characterized in that the materially bonded connection of the connection element ( 90 ) to the magnet core ( 66 ) in the first connection region ( 92 ) is a welded connection. 16. The inlet valve as claimed in claim 10 , wherein the connection element ( 90 ) is further connected to the carrier element ( 78 ) in a materially bonded manner in a third connection region ( 92 ) and in a form-fitting manner in a fourth connection region ( 94 ) which is offset from the third connection region ( 92 ) in a direction of a longitudinal axis ( 91 ) of the connection element ( 90 ). 17. The inlet valve as claimed in claim 16 , wherein the first connection region ( 92 ) on the magnet core ( 66 ) is a welded connection, wherein the second connection region ( 94 ) on the magnet core ( 66 ) is a plastic deformation of the connection element ( 90 ) into a depression ( 96 ) in the magnet core ( 66 ) so as to form the preload between the first connection region ( 92 ) on the magnet core ( 66 ) and the second connection region ( 94 ) on the magnet core ( 66 ), wherein the third connection region ( 92 ) on the c