Electrical isolation of angle of attack vane bearings

The invention claimed is: 1. An angle of attack vane mounting system comprising: a mounting flange secured to an aircraft; a shaft extending through the mounting flange; a bearing disposed between the mounting flange and the shaft, wherein the bearing comprises: an inner race attached to the shaft; and an outer race attached to the mounting flange; and an electric isolator disposed adjacent one of the inner race and the outer race and electrically isolating the bearing such that an electric current is prevented from passing between the inner race and the outer race; wherein the electric isolator comprises at least one of a first sleeve disposed between the shaft and the inner race and a second sleeve disposed between the mounting flange and the outer race. 2. The angle of attack vane mounting system of claim 1 , wherein the electric isolator further includes a ceramic rolling element disposed between the inner race and the outer race. 3. The angle of attack vane mounting system of claim 1 , wherein the shaft comprises a dielectric material. 4. An angle of attack vane for an aircraft, the angle of attack vane comprising: an outboard mounting flange; an inboard mounting flange disposed adjacent the outboard mounting flange; a shaft extending through the outboard mounting flange and the inboard mounting flange; an inboard bearing rotatably supporting the shaft and disposed between the shaft and the inboard mounting flange; an inboard electric isolator configured to prevent an electric current from traveling through the inboard bearing; an outboard bearing rotatably supporting the shaft and disposed between the outboard mounting flange and the shaft; an outboard electric isolator configured to prevent an electric current from traveling through the outboard bearing; and a vane extending from the shaft outboard of the outboard mounting flange; wherein the inboard electric isolator comprises at least one of a first sleeve disposed about the shaft and adjacent an inner race of the inboard bearing and a second sleeve disposed between the inboard mounting flange and an outer race of the inboard bearing; and wherein the outboard electric isolator comprises at least one of a third sleeve disposed about the shaft and adjacent an inner race of the outboard bearing and a fourth sleeve disposed between the outboard mounting flange and an outer race of the outboard bearing. 5. The angle of attack vane of claim 4 , wherein the inboard electric isolator comprises: a ceramic inboard rolling ball disposed between an inboard inner race of the inboard bearing and an inboard outer race of the inboard bearing, wherein the ceramic inboard rolling ball is configured to prevent an electric current from passing between the inboard inner race and the inboard outer race. 6. The angle of attack vane of claim 5 , wherein the inboard inner race is formed from a first dielectric material and the inboard outer race is formed from a second dielectric material. 7. The angle of attack vane of claim 6 , wherein each of the first dielectric material and the second dielectric material comprise one of a ceramic, an engineered plastic, or a composite material. 8. The angle of attack vane of claim 4 , wherein the outboard mounting flange comprises a dielectric material. 9. The angle of attack vane of claim 4 , wherein the shaft comprises a dielectric material. 10. The angle of attack vane of claim 4 , wherein the inboard mounting flange comprises a dielectric material. 11. An angle of attack vane for an aircraft, the angle of attack vane comprising: an outboard mounting flange; an inboard mounting flange disposed adjacent the outboard mounting flange; a shaft extending through the outboard mounting flange and the inboard mounting flange; an inboard bearing rotatably supporting the shaft and disposed between the shaft and the inboard mounting flange; an inboard electric isolator configured to prevent an electric current from traveling through the inboard bearing; an outboard bearing rotatably supporting the shaft and disposed between the outboard mounting flange and the shaft; an outboard electric isolator configured to prevent an electric current from traveling through the outboard bearing; and a vane extending from the shaft outboard of the outboard mounting flange; wherein a grounding element is disposed about the shaft and configured to ground the shaft to a fuselage of the aircraft. 12. The angle of attack vane of claim 11 , wherein the grounding element comprises one of a grounding brush and a grounding ring. 13. A method of preventing lightning strike damage to a bearing of an angle of attack vane, the method comprising: mounting an angle of attack vane shaft on a bearing disposed between the angle of attack vane shaft and a mounting flange; and electrically isolating the bearing such that an electrical current cannot pass between an inner race of the bearing and an outer race of the bearing; wherein electrically isolating the bearing includes at least one of: mounting a dielectric sleeve on the shaft between the shaft and the inner race; and mounting a dielectric sleeve on a mounting flange adjacent the outer race of the bearing. 14. The method of claim 13 , wherein the step of electrically isolating the bearing such that an electrical current cannot pass between an inner race of the bearing and an outer race of the bearing comprises: mounting a ceramic rolling element between the inner race and the outer race. 15. A method of preventing lightning strike damage to a bearing of an angle of attack vane, the method comprising: mounting an angle of attack vane shaft on a bearing disposed between the angle of attack vane shaft and a mounting flange; and electrically isolating the bearing such that an electrical current cannot pass between an inner race of the bearing and an outer race of the bearing; wherein electrically isolating the bearing includes mounting a grounding element on the shaft adjacent the bearing, such that the shaft is grounded to an aircraft.