System, method and apparatus for metallic gear hub with metallic teeth having outer polymer layer

We claim: 1. A gear, comprising: a metallic gear hub consisting of a monolithic gear core having an axis of rotation and metallic gear teeth that have roll, pitch and yaw axes and are smaller than a final gear teeth size of the gear; wherein the metallic gear teeth are not co-planar with each other such that at least some of the metallic gear teeth are offset from each other, and the metallic gear teeth are oriented at a roll angle relative to the axis, and the roll angle is in a range of about 30 degrees to about 60 degrees relative to neutral; and a polymer layer on the metallic gear teeth to form polymer gear teeth on the metallic gear teeth, wherein the polymer gear teeth comprise the final gear teeth size of the gear, such that the metallic gear hub is configured to fully support a contact line of a mating gear. 2. The gear of claim 1 , wherein each of the metallic gear teeth comprises a shape that is rectangular with rounded corners. 3. The gear of claim 1 , wherein both pitch and yaw angles of the metallic gear teeth are neutral. 4. The gear of claim 1 , wherein the polymer gear teeth are not offset from each other. 5. The gear of claim 1 , wherein the metallic gear teeth comprise an alternating axial pattern on the metallic gear hub. 6. The gear of claim 1 , wherein the metallic gear teeth comprise a metal axial width, and the polymer gear teeth comprise a polymer axial width that is at least double the metal axial width. 7. The gear of claim 1 , wherein a polymer axial width of the polymer gear teeth exceeds a metallic axial width of the metallic gear teeth. 8. The gear of claim 1 , wherein said at least some of the metallic gear teeth are axially offset from each other. 9. The gear of claim 1 , wherein the metallic gear teeth comprise overhangs that extend in opposite axial directions. 10. The gear of claim 9 , wherein an overhang outer axial dimension between opposite ones of the overhangs exceed a hub outer axial dimension of the metallic gear hub. 11. The gear of claim 1 wherein the polymer gear teeth are not axially offset from each other. 12. The gear of claim 1 , wherein the polymer gear teeth do not comprise an alternating pattern. 13. The gear of claim 1 , wherein the metallic gear teeth comprise a metal axial width, and the polymer gear teeth comprise a polymer axial width that is at least triple the metal axial width. 14. The gear of claim 1 , wherein the metallic gear teeth comprise a metal axial width, and the polymer gear teeth comprise a polymer axial width that is at least quadruple the metal axial width. 15. The gear of claim 1 , wherein at least one of a shape, length and direction of the metallic gear teeth can be complementary to a contact line on a helical gear or a mating worm shaft. 16. The gear of claim 15 , wherein the polymer layer is fully supported by the metallic gear teeth along an entirety of the contact line. 17. The gear of claim 1 , wherein the metallic gear teeth comprise two rows that are parallel to each other. 18. A gear, comprising: a metallic gear hub consisting of a monolithic gear core having an axis of rotation and metallic gear teeth that have roll, pitch and yaw axes and are smaller than a final gear teeth size of the gear; wherein the metallic gear teeth are oriented at a roll angle relative to the axis, and the roll angle is in a range of about 30 degrees to about 60 degrees relative to neutral; the metallic gear teeth are not co-planar with each other such that at least some of the metallic gear teeth are offset from each other; and a polymer layer on the metallic gear teeth to form polymer gear teeth on the metallic gear teeth, wherein the polymer gear teeth comprise the final gear teeth size of the gear. 19. A gear, comprising: a metallic gear hub consisting of a monolithic gear core having an axis of rotation and metallic gear teeth that have roll, pitch and yaw axes and are smaller than a final gear teeth size of the gear; wherein the metallic gear teeth are not co-planar with each other such that at least some of the metallic gear teeth are offset from each other; the metallic gear teeth comprise overhangs that extend in opposite axial directions, wherein an overhang outer axial dimension between opposite ones of the overhangs exceed a hub outer axial dimension of the metallic gear hub; and a polymer layer on the metallic gear teeth to form polymer gear teeth on the metallic gear teeth, wherein the polymer gear teeth comprise the final gear teeth size of the gear.