Device for the controllable metering of hydrogen and method for the production thereof

What is claimed is: 1 . A method for producing a device for the feedback-controllable metering of hydrogen, the method comprising: providing a valve seat in a body; providing a movable sealing element to seal against the valve seat; providing an electromagnetic actuator with a pole core, a solenoid, and an armature coupled to the sealing element, wherein the actuator moves the sealing element along an axis as a function of an electric current in the solenoid; wherein the pole core and the solenoid are fixed against movement in relation to the body; wherein the actuator is disposed between the pole core and the sealing element; and attaching a compression spring between the armature and the pole core onto a pin attached in the armature for centering the compression spring; wherein a surface of the pole core forms a conical extension having two separate conical profiles and having a cylindrical bore extending from the surface into the pole core; the compression spring is disposed within the cylindrical bore of the pole core and the pin extends from the armature into the cylindrical bore of the pole core within the compression spring; a surface of the armature forms a conical depression with two separate conical profiles; and the surface of the pole core and the surface of the armature conjointly form a double cone by interaction of the two respective separate conical profiles. 2 . A device for the feedback-controllable metering of hydrogen, the device comprising: a body; a valve seat; a sealing element; an electromagnetic actuator having a pole core, a solenoid, and an armature coupled to the sealing element, wherein the actuator moves the sealing element along an axis as a function of an electric current in the solenoid; wherein the pole core and the solenoid are fixed against movement in relation to the body; wherein the actuator is disposed between the pole core and the sealing element; a compression spring attached between the armature and the pole core; and a pin attached in the armature for centering the compression spring; wherein a surface of the pole core forms a conical extension having two separate conical profiles and having a cylindrical bore extending from the surface into the pole core; the compression spring is disposed within the cylindrical bore of the pole core and the pin extends from the armature into the cylindrical bore of the pole core within the compression spring; a surface of the armature forms a conical depression with two separate conical profiles; and the surface of the pole core and the surface of the armature conjointly form a double cone by interaction of the two respective separate conical profiles. 3 . The device as claimed in claim 2 , wherein: the surface of the pole core has at least one first pole core surface region having a first pole core cone angle, and a second pole core surface region having a second pole core cone angle; and the surface of the armature has at least one first armature surface region having a first armature cone angle, and a second armature surface region having a second armature cone angle. 4 . The device as claimed in claim 3 , wherein: the first pole core surface region and the first armature surface region are in each case closer to the sealing element than the second pole core surface region and the second armature surface region; and the first pole core cone angle and the first armature cone angle are in each case smaller than the second pole core cone angle and the second armature cone angle. 5 . The device as claimed in claim 3 , wherein: the first pole core cone angle is equal to the first armature cone angle; and/or the second pole core cone angle is equal to the second armature cone angle. 6 . The device as claimed in claim 2 , further comprising a circuit for energizing the solenoid; wherein the circuit comprises a pulse width modulator with a variable frequency which is configured for varying the frequency as a function of voltage, duty cycle of the pulse width modulator, and the coil current. 7 . The device as claimed in claim 2 , wherein the sealing element has a surface which tapers axially in the direction of the valve seat and which has at least two portions each having a different angle of inclination relative to the axis. 8 . The device as claimed in claim 2 , having a characteristic curve representing a correlation between mass flow and coil current, which has at least two linear portions each with a different gradient. 9 . The device as claimed in claim 2 , wherein the electromagnetic actuator is disposed on a high-pressure side of the device.