Valve, in particular a suction valve, in a high-pressure pump of a fuel injection system

The invention claimed is: 1. A valve for a high-pressure pump ( 1 ) of a fuel injection system, the valve comprising a magnetic actuator ( 22 ), which has a magnet coil ( 6 ), a magnet armature ( 10 ) configured to perform a stroke motion, and a pole core ( 20 ), wherein the magnet armature ( 10 ) and the pole core ( 20 ) together delimit a working air gap ( 28 ), and the magnet armature ( 10 ) is configured to come into contact at least indirectly with the pole core ( 20 ), wherein the valve also comprises a valve element ( 14 ) which is configured to be moved between an open position and a closed position, and which is at least indirectly in mechanical contact with the magnet armature ( 10 ), characterized in that at least one of a separate magnet armature insert ( 8 ) arranged in the magnet armature ( 10 ) and a separate pole core insert ( 24 ) arranged in the pole core ( 20 ) is provided in a region of contact of the magnet armature ( 10 ) with the pole core ( 20 ), such that the magnet armature ( 10 ) comes into contact with the pole core ( 20 ) via the at least one of a separate magnet armature insert ( 8 ) arranged in the magnet armature ( 10 ) and a separate pole core insert ( 24 ) arranged in the pole core ( 20 ). 2. A pump comprising a valve as claimed in claim 1 . 3. The valve as claimed in claim 1 wherein the valve comprises the separate magnet armature insert ( 8 ) arranged in the magnet armature ( 10 ) in the region of contact of the magnet armature ( 10 ) with the pole core ( 20 ). 4. The valve as claimed in claim 3 , characterized in that the magnet armature insert ( 8 ) is introduced into a first recess ( 42 ) in the magnet armature ( 10 ), said recess facing the pole core ( 20 ). 5. The valve as claimed in claim 4 , characterized in that the magnet armature insert ( 8 ) is configured in such a way that the magnet armature insert ( 8 ) projects from the first recess ( 42 ) in the magnet armature ( 10 ) on a side facing the pole core ( 20 ), and is in contact with the valve element ( 14 ) on a side of the magnet armature ( 10 ) which faces away from the pole core ( 20 ). 6. The valve as claimed in claim 4 , characterized in that the magnet armature insert ( 8 ) is configured in such a way that the magnet armature insert ( 8 ) projects from the first recess ( 42 ) in the magnet armature ( 10 ) on a side facing the pole core ( 20 ), and is in contact with the valve element ( 14 ) on a side of the magnet armature ( 10 ) which faces away from the pole core ( 20 ), and projects beyond a surface of the magnet armature ( 10 ) on a side facing the valve element ( 14 ). 7. The valve as claimed in claim 3 , characterized in that the magnet armature insert ( 8 ) has a first collar ( 50 ) on a side facing the pole core ( 20 ), said collar projecting in an axial direction from a surface of the magnet armature ( 10 ) which faces the pole core ( 20 ) and/or said collar having a first enlarged outside diameter in comparison with an outside diameter of the magnet armature insert ( 8 ) in a remaining region thereof. 8. The valve as claimed in claim 7 , characterized in that the first collar ( 50 ) of the magnet armature insert ( 8 ) is supported in an axial direction on a first shoulder ( 44 ) of the magnet armature ( 10 ), said shoulder being formed circumferentially on an inside diameter of the magnet armature ( 10 ). 9. The valve as claimed in claim 3 , characterized in that the magnet armature insert ( 8 ) is composed of a material which has a higher strength than the material of the magnet armature ( 10 ). 10. The valve as claimed in claim 3 , characterized in that a material of the magnet armature insert ( 8 ) is nonmagnetic. 11. The valve as claimed in claim 3 , characterized in that a second compression spring ( 12 ) projects into a second recess ( 48 ) in the magnet armature insert ( 8 ), wherein the second compression spring ( 12 ) is arranged between the magnet armature ( 10 ) and the pole core ( 20 ) and the second compression spring ( 12 ) exerts an axial and mutually opposed force on the magnet armature ( 10 ) and the pole core ( 20 ). 12. The valve as claimed in claim 3 , characterized in that a second compression spring ( 12 ) projects into a second recess ( 48 ) in the magnet armature insert ( 8 ) and is guided in the radial and/or axial direction, wherein the second compression spring ( 12 ) is arranged between the magnet armature ( 10 ) and the pole core ( 20 ) and the second compression spring ( 12 ) exerts an axial and mutually opposed force on the magnet armature ( 10 ) and the pole core ( 20 ). 13. The valve as claimed in claim 1 wherein the valve comprises the separate pole core insert ( 24 ) arranged in the pole core ( 20 ) in the region of contact of the magnet armature ( 10 ) with the pole core ( 20 ). 14. The valve as claimed in claim 13 , characterized in that the pole core insert ( 24 ) has a second collar ( 62 ) on a side facing the magnet armature ( 10 ), said second collar projecting in an axial direction from a surface of the pole core ( 20 ) which faces the magnet armature ( 10 ) and/or said second collar having a second enlarged outside diameter in comparison with an outside diameter of the pole core insert ( 24 ) in a remaining region thereof. 15. The valve as claimed in claim 14 , characterized in that the second collar ( 62 ) of the pole core insert ( 24 ) is supported in an axial direction on a third shoulder ( 56 ) of the pole core ( 20 ), said shoulder being formed circumferentially on the inside diameter of the pole core ( 20 ). 16. The valve as claimed in claim 13 , characterized in that the pole core insert ( 24 ) is introduced into a third recess ( 54 ) in the pole core ( 20 ), said recess facing the magnet armature ( 10 ). 17. The valve as claimed in claim 13 , characterized in that the pole core insert ( 24 ) is composed of a material which has a higher strength than a material of the pole core ( 20 ). 18. The valve as claimed in claim 13 , characterized in that a material of the pole core insert ( 24 ) is nonmagnetic. 19. The valve as claimed in claim 13 , characterized in that a second compression spring ( 12 ) projects into a fourth recess ( 60 ) in the pole core insert ( 24 ), wherein the second compression spring ( 12 ) is arranged between the magnet armature ( 10 ) and the pole core ( 20 ) and the second compression spring ( 12 ) exerts an axial and mutually opposed force on the magnet armature ( 10 ) and the pole core ( 20 ). 20. The valve as claimed in claim 13 , characterized in that a second compression spring ( 12 ) projects into a fourth recess ( 60 ) in the pole core insert ( 24 ) and is guided in the radial and/or axial direction, wherein the second compression spring ( 12 ) is arranged between the magnet armature ( 10 ) and the pole core ( 20 ) and the second compression spring ( 12 ) exerts an axial and mutually opposed force on the magnet armature ( 10 ) and the pole core ( 20 ). 21. A valve for a high-pressure pump ( 1 ) of a fuel injection system, the valve comprising a magnetic actuator ( 22 ), which has a magnet coil ( 6 ), a magnet armature ( 10 ) configured to perform a stroke motion, and a pole core ( 20 ), wherein the magnet armature ( 10 ) and the pole core ( 20 ) together delimit a working air gap ( 28 ), and the magnet armature ( 10 ) is configured to come into contact at least indirectly with the pole core ( 20 ), wherein the valve also comprises a valve element ( 14 ) which is configured to be moved between an open position and a closed position,