Final position locking feature of multi-turn rotational device having an axially translating wheel or a clocked lock passage gear

What we claim is: 1. Apparatus, including a valve, comprising a cover configured to rotate, and having a biased-pin mounted therein, a valve housing, and at least one inner housing component having a circumferential surface configured with a hole or slot formed therein at a predetermined location to receive the biased-pin where the biased-pin is engaged in the hole or slot when the valve is calibrated to be at a final position; and the cover configured to rotate in relation to the valve housing and the at least one inner housing component and cause an axial translation between the cover and the at least one inner housing component in response to a rotation of the cover, so that the biased-pin bypasses the hole or slot formed in the circumferential surface when the cover and the at least one inner housing component have not yet moved far enough along the axis of translation, and so that the biased-pin engages the hole or slot formed in the circumferential surface when the valve is at the final position so as to stop any further axial and rotational movement. 2. Apparatus according to claim 1 , wherein the biased-pin comprises a spring-pin having a combination of a pin and biasing member configured to urge the spring-pin inwardly towards the at least one inner component. 3. Apparatus according to claim 1 , wherein the biased-pin is configured to be pulled outwardly to disengage the hole or slot in the at least one inner housing components so as to allow further rotational movement, including forward and reverse rotational movement. 4. Apparatus according to claim 1 , wherein the cover is configured to rotate in an axis of rotation that is substantially parallel to the axis of translation. 5. Apparatus, including a valve, comprising a cover configured with a biased-pin mounted therein, and at least one inner housing component having a circumferential surface configured with a hole or slot formed therein at a predetermined location to receive the biased-pin where the biased-pin is engaged in the hole or slot when the valve is calibrated to be at a final position; and the cover configured to rotate and cause an axial translation between the cover and the at least one inner housing component so that the biased-pin bypasses the hole or slot formed in the circumferential surface when the cover has not yet moved far enough along the axis of translation and engages the hole or slot formed in the circumferential surface when the valve is at the final position so as to stop any further axial and rotational movement, wherein the cover is configured to rotate and move along the axis of translation in relation to the at least one inner housing component; the biased-pin comprises a head portion and an end portion; and the head portion is configured to visually indicate when the valve is at the final position, the end portion is fully engaged in hole or slot of the at least one inner housing component, including where the head portion is flush with an outer surface of the cover. 6. Apparatus comprising: a cover configured with a biased-pin mounted therein, and at least one inner housing component configured with a hole or slot formed at a predetermined location where the biased-pin is at when the valve is calibrated to be at a final position; and the cover configured to rotate and cause an axial translation between the cover and the at least one inner housing component so that the biased-pin engages the hole or slot when the valve is at the final position so as to stop any further axial and rotational movement; wherein the cover is configured to rotate in relation to the at least one inner housing component; the cover comprises a rotating component configured with threads; the at least one inner housing component comprises a stem portion configured with corresponding threads; and the threads and the corresponding threads are configured to cooperate and cause the axial translation between the cover and the at least one inner housing component when the cover is rotated. 7. Apparatus comprising: a cover configured with a biased-pin mounted therein, and at least one inner housing component configured with a hole or slot formed at a predetermined location where the biased-pin is engaged in the hole when the valve is calibrated to be at a final position; and the cover configured to rotate and cause the at least one inner housing component to rotate so that the biased-pin engages the hole or slot when the valve is at the final position so as to stop any further axial and rotational movement; wherein the at least one inner housing component comprises a locking gear configured with a gear toothed surface having at least part of the hole or slot formed therein so as to form a gear cutout. 8. Apparatus according to claim 7 , wherein the at least one inner housing component comprises threaded gears and a central gear and is configured to respond to the rotational movement of the cover and rotate the threaded gears so as to cause the axial translation between the cover and the at least one inner housing component. 9. Apparatus according to claim 8 , wherein the locking gear comprises an outer surface configured with associated teeth and is configured with an unthreaded central bore hole; the at least one inner housing component comprises a pivot portion configured to receive the unthreaded central bore hole of the locking gear; and the associated teeth of the locking gear and corresponding teeth of the central gear are configured to cooperate and cause the locking gear to rotate when the cover is rotated. 10. Apparatus according to claim 8 , wherein each threaded gear is configured with gear teeth; the central gear is configured with corresponding gear teeth; and the gear teeth and the corresponding gear teeth are configured to cooperate and cause the axial translation between the cover and the at least one inner housing component when the cover is rotated. 11. Apparatus according to claim 10 , wherein each threaded gear is configured to translate down in response to the rotational movement of the cover. 12. Apparatus according to claim 11 , wherein the locking gear is configured to rotate and spin in response to the rotational movement of the cover coinciding with the downward translation of the threaded gears. 13. Apparatus according to claim 7 , wherein the at least one inner housing component comprises a circumferential surface; and the biased-pin comprises an end portion and is mounted in the cover so that part of the end portion rests against a corresponding part of some combination of the circumferential surface, the gear toothed surface of the locking gear, or both, until the valve is at the final position and at least part of the end portion drops into the gear cutout. 14. Apparatus according to claim 13 , wherein the circumferential surface comprises a corresponding cut or slot configured to receive at least part of the end portion when the valve is at the final position. 15. Apparatus according to claim 7 , wherein the locking gear is configured with a different number of teeth or diameter than the center gear in order for the locking gear to have a unique rotational position with each rotation, calibrating for alignment of the gear cutout and spring-pin in the final position. 16. Apparatus, including a valve, comprising: a cover configured with a biased-pin mounted therein, and at least one inner housing component having a circumferential surface configured with a hole or slot formed therein at a redetermined location to receive the biased-pin where the biased-pin is engaged in the h