Pressure control valve for a fuel injection system

The invention claimed is: 1. A pressure control valve for a fuel injection system configured to control a pressure in a high-pressure fuel accumulator, comprising: a spherical valve closing element; a valve piece defining a valve seat with a conical form, the valve seat configured to interact with the spherical valve closing element, the valve piece formed as a one-piece, unitary body; and a solenoid actuator configured to actuate the spherical valve closing element, and to interact with an armature configured to perform a stroke movement, the armature connected to an armature pin and configured to transmit a force of the solenoid actuator to the spherical valve closing element, wherein the valve piece further defines a first guide region and a second guide region arranged axially above the first guide region, the spherical valve closing element guided in an axially displaceable direction in the valve piece by the first guide region, the armature pin guided in the axially displaceable direction in the valve piece by the second guide region, wherein the first guide region has at least two first guide surfaces configured to delimit a radial movement of the spherical valve closing element, wherein the second guide region has at least two second guide surfaces configured to delimit a radial movement of the armature pin, and wherein the at least two first guide surfaces directly adjoin the valve seat via first radially running webs. 2. The pressure control valve as claimed in claim 1 , wherein: the at least two second guide surfaces are formed on second radially running webs, and the first radially running webs and the second radially running webs delimit flow ducts. 3. The pressure control valve as claimed in claim 2 , wherein at least a part of the flow ducts is hydraulically connected to an armature chamber. 4. The pressure control valve as claimed in claim 1 , wherein in a cross section of the valve piece, the at least two first guide surfaces form tangents to an outer diameter of the spherical valve closing element, and the at least two second guide surfaces form tangents to an outer diameter of the armature pin. 5. The pressure control valve as claimed in claim 1 , wherein the valve piece is a metal injection molded part. 6. The pressure control valve as claimed in claim 1 , wherein the valve piece has a biting edge on a support surface averted from the valve seat. 7. The pressure control valve as claimed in claim 1 , wherein the pressure control valve is configured as a 2/2 directional valve. 8. The pressure control valve as claimed in claim 1 , wherein: the at least two second guide surfaces are formed on second radially running webs, and the first radially running webs are connected to the second radially running webs via a conical surface of the valve seat. 9. The pressure control valve as claimed in claim 1 , wherein: the at least two second guide surfaces are formed on second radially running webs, and the first radially running webs and the second radially running webs are arranged at uniform angular intervals with respect to one another. 10. The pressure control valve as claimed in claim 9 , wherein the first radially running webs and the second radially running webs delimit flow ducts. 11. The pressure control valve as claimed in claim 2 , further comprising a valve housing interposed between the valve piece and the armature, the valve housing formed as a one-piece, unitary body, wherein the valve piece defines a valve chamber and the valve housing defines an armature chamber spaced from valve chamber, the armature chamber hydraulically connected to the valve chamber via the flow ducts. 12. The pressure control valve as claimed in claim 4 , wherein: the spherical valve closing element has a punctiform contact region with at least one of the at least two first guide surfaces when the spherical valve closing element is guided by the first guide region, and the armature pin has a linear contact region with at least one of the at least two second guide surfaces when the armature pin is guided by the second guide region. 13. A pressure control valve for a fuel injection system configured to control a pressure in a high-pressure fuel accumulator, comprising: a spherical valve closing element; a valve piece defining a valve seat with a conical form, the valve seat configured to interact with the spherical valve closing element, the valve piece formed as a one-piece, unitary body; and a solenoid actuator configured to actuate the spherical valve closing element, and to interact with an armature configured to perform a stroke movement, the armature connected to an armature pin and configured to transmit a force of the solenoid actuator to the spherical valve closing element, wherein the valve piece further defines a first guide region and a second guide region arranged axially above the first guide region, the spherical valve closing element guided in an axially displaceable direction in the valve piece by the first guide region, the armature pin guided in the axially displaceable direction in the valve piece by the second guide region, wherein the first guide region has at least two first guide surfaces configured to delimit a radial movement clearance of the spherical valve closing element, wherein the second guide region has at least two second guide surfaces configured to delimit a radial movement clearance of the armature pin, wherein the at least two first guide surfaces directly adjoin the valve seat via first radially running webs, wherein the at least two second guide surfaces are formed on second radially running webs, and wherein the first radially running webs and the second radially running webs are arranged at uniform angular intervals with respect to one another. 14. A pressure control valve for a fuel injection system configured to control a pressure in a high-pressure fuel accumulator, comprising: a spherical valve closing element; a valve piece defining a valve seat with a conical form, the valve seat configured to interact with the spherical valve closing element, the valve piece formed as a one-piece, unitary body; a solenoid actuator configured to actuate the spherical valve closing element, and to interact with an armature configured to perform a stroke movement, the armature connected to an armature pin and configured to transmit a force of the solenoid actuator to the spherical valve closing element; and a valve housing interposed between the valve piece and the armature, the valve housing formed as a one-piece, unitary body, wherein the valve piece further defines a first guide region and a second guide region arranged axially above the first guide region, the spherical valve closing element guided in an axially displaceable direction in the valve piece by the first guide region, the armature pin guided in the axially displaceable direction in the valve piece by the second guide region, wherein the first guide region has at least two first guide surfaces configured to delimit a radial movement clearance of the spherical valve closing element, and wherein the second guide region has at least two second guide surfaces configured to delimit a radial movement clearance of the armature pin, wherein the at least two first guide surfaces directly adjoin the valve seat via first radially running webs, wherein the at least two second guide surfaces are formed on second radially running webs, wherein the first radially running webs and the second radially running webs delimit flow ducts, and wherein the valve piece defines a valve chamber and the valve housing defines an armat