System and method for a wheel lock ring assembly

The invention claimed is: 1. A wheel assembly comprising: a wheel base; a side rim disposed about a circumference of the wheel base, wherein the side rim includes an inside surface; and a lock ring that secures the side rim onto the wheel base, the lock ring preventing the side rim from sliding axially off the wheel base, wherein the lock ring comprises four discrete non-contiguous interfaces with interior surfaces of the wheel base and the side rim, wherein the lock ring comprises a single unitary member wherein the lock ring is a cam lock ring which engages in response to a tire inflation. 2. The wheel assembly of claim 1 , wherein torque transfer paths are created through the lock ring via the discrete non-contiguous interfaces. 3. The wheel assembly of claim 1 , wherein the lock ring is marked with an indicator to assist with wheel assembly construction. 4. The wheel assembly of claim 1 , wherein a torque transfer capacity of the lock ring is optimized by proportioning surface contact stress among the four discrete non-contiguous interfaces with interior surfaces of the wheel base and the side rim. 5. The wheel assembly of claim 1 , wherein a faulty lock ring is indicated in response to an air seal disengaging the inside surface. 6. The wheel assembly of claim 1 , wherein the lock ring comprises at least one fillet between two of the non-contiguous interfaces. 7. The wheel assembly of claim 6 , wherein the lock ring comprises a cross-sectional profile that is generally Z shaped. 8. The wheel assembly of claim 1 , wherein the lock ring is comprised of a deformable material. 9. The wheel assembly of claim 1 , wherein the lock ring comprises at least one chamfer between two of the non-contiguous interfaces. 10. The wheel assembly of claim 1 , wherein the lock ring is coated with at least one of a polytetrafluoroethylene and molybdenum disulfide surface coating. 11. The wheel assembly of claim 1 , wherein the lock ring comprises four discrete non-contiguous interfaces with interior surfaces of the wheel base and the side rim, as viewed along a cross-section of the lock ring oriented along a plane passing through an axis of rotation of the wheel base. 12. The wheel assembly of claim 9 , wherein the lock ring is comprised of a material comprising at least one of steel, a poly matrix composite and an aluminum alloy. 13. The wheel assembly of claim 1 , wherein the wheel assembly comprises a cavity including a bottom surface formed on the wheel base and a top surface formed on the inside surface of the side rim, the top surface being substantially parallel to the bottom surface. 14. The wheel assembly of claim 13 , wherein the cavity includes a first side surface formed on the inside surface of the side rim and a second side surface formed on the wheel base, the first side surface being substantially parallel to the second side surface. 15. The wheel assembly of claim 14 , wherein the bottom surface, the first side surface, the top surface and the second side surface of the cavity respectively contact the lock ring via the four discrete non-contiguous interfaces. 16. A method for assembling a wheel assembly, the method comprising: placing a wheel base inside a tire, the wheel base having an air seal seat; placing a side rim inside the tire around the wheel base; moving the side rim on the wheel base to expose the air seal seat; placing an air seal around the wheel base and inside the air seal seat; inserting a lock ring inside a cavity between the wheel base and the side rim, the lock ring comprising four discrete non-contiguous interfaces with interior surfaces of the wheel base and the side rim, wherein the lock ring comprises a single lock ring, wherein the lock ring is a cam lock ring which engages in response to a tire inflation; and inflating the tire. 17. The method of claim 16 , wherein torque transfer paths are created through the lock ring via the discrete non-contiguous interfaces. 18. The method of claim 16 , wherein the lock ring comprises at least one of a fillet and a chamfer between two of the non-contiguous interfaces. 19. A wheel assembly comprising: a wheel base; a side rim disposed about a circumference of the wheel base, wherein the side rim includes an inside surface; and a lock ring that secures the side rim onto the wheel base, the lock ring preventing the side rim from sliding axially off the wheel base, wherein the lock ring comprises four discrete non-contiguous interfaces with interior surfaces of the wheel base and the side rim, wherein the lock ring comprises a single unitary member, wherein a torque transfer capacity of the lock ring is optimized by proportioning surface contact stress among the four discrete non-contiguous interfaces with interior surfaces of the wheel base and the side rim.