Compressor system with purge gas system

What is claimed is: 1. A system operative to flow a working fluid, comprising: a compressor comprising a rotor, wherein the rotor is supported by a bearing in a bearing cavity; the compressor rotor having a first surface that moves relative to a second surface of the bearing, the first surface and the second surface having a near frictionless diamond-like carbon (NFDLC) coating, the near frictionless diamond-like carbon coating constructed to cause the first surface and the second surface to repel each other; and a purge gas system in fluid communication with the bearing cavity and constructed to generate a purge gas from the working fluid, the purge gas being compositionally different than the working fluid, the purge gas system being constructed to purge the bearing cavity and supply the bearing cavity with the purge gas during operation of the system, wherein the purge gas has a nitrogen content greater than that of the working fluid. 2. The system of claim 1 , wherein the purge gas system includes a purge gas storage tank in fluid communication with the bearing cavity. 3. The system of claim 2 , wherein the working fluid is air, and wherein the purge gas includes nitrogen; further comprising a nitrogen generator constructed to generate the purge gas from the air. 4. The system of claim 3 , wherein the compressor rotor is rotated to compress air as the working fluid, the nitrogen generator being in fluid communication with the compressor and constructed to generate the nitrogen from compressed air received from the compressor. 5. The system of claim 4 further comprising an air-water separator and/or a dryer for reducing or eliminating water and/or water vapor from the compressed air prior to delivery of the compressed air to the nitrogen generator, wherein the nitrogen discharged from the nitrogen generator is dry nitrogen. 6. The system of claim 4 , wherein the compressor includes a discharge end, the bearing cavity being disposed at the discharge end, further comprising a gas amplifier constructed to increase the pressure of the purge gas to being above a discharge pressure of the compressor. 7. The system of claim 6 , wherein the gas amplifier is a mechanical gas amplifier. 8. The system of claim 4 , wherein the compressor includes an inlet end, the bearing cavity being disposed at the inlet end, further comprising a valve constructed to reduce the pressure of the purge gas prior to entry of the purge gas into the bearing cavity. 9. A compressor system operative to compress a working fluid, comprising: a compressor having a rotor with a first surface supported by a bearing having a second surface which faces the first surface, the first surface and the second surface each having a near frictionless diamond-like carbon coating and being disposed in a cavity, where the near frictionless diamond-like carbon coating is constructed to cause the first surface and the second surface to repel each other; and a purge gas system in fluid communication with the cavity, the purge gas system being constructed to discourage oxidation of the near frictionless diamond-like carbon coating, the purge gas system having a nitrogen generator constructed to generate a purge gas from the working fluid and having a different composition than the working fluid, the purge gas having a nitrogen content greater than that of the working fluid, the purge gas system being constructed to purge the cavity and supply the cavity with the purge gas, such that the purge gas flows from the cavity to the rotor to prevent the ingress of the working fluid into the cavity. 10. The compressor system of claim 9 , wherein the purge gas system includes a nitrogen storage tank in fluid communication with the cavity. 11. The compressor system of claim 9 , wherein the working fluid is air; and wherein the nitrogen generator is in fluid communication with the compressor and constructed to generate the purge gas from compressed air received from the compressor. 12. The compressor system of claim 11 , further comprising an air-water separator and/or a dryer for reducing or eliminating water and/or water vapor from the compressed air prior to delivery of the compressed air to the nitrogen generator, wherein the nitrogen generated by the nitrogen generator is dry nitrogen. 13. The compressor system of claim 11 , wherein a flow of the purge gas is substantially less than a flow of the working fluid. 14. The compressor system of claim 9 , further comprising an external compressed air source, wherein the nitrogen generator is in fluid communication with the external compressed air source and constructed to receive compressed air from the external compressed air source; and wherein the nitrogen generator is constructed to generate the purge gas from the compressed air received from the external compressed air source and to purge the cavity with the purge gas when the compressor is not running. 15. The compressor system of claim 9 , wherein the compressor includes a discharge end, and the cavity is disposed at the discharge end, further comprising a gas amplifier constructed to increase the pressure of the purge gas. 16. The compressor system of claim 15 , wherein the gas amplifier is a mechanical gas amplifier. 17. The compressor system of claim 15 , wherein the gas amplifier is coupled to the discharge end of the compressor and is constructed to increase the pressure of the purge gas using the pressure of compressed working fluid discharged by the compressor. 18. A method of operating a compressor, comprising: rotating a rotor of the compressor to compress air; operating a purge gas system having a nitrogen generator constructed to generate a purge gas from compressed air; during the rotating, repelling a first surface of the rotor which has a near frictionless diamond-like carbon (NFDLC) coating from a second surface of a bearing which has a near frictionless diamond-like carbon (NFDLC) coating, the bearing being disposed in a bearing cavity of the compressor; purging the bearing cavity of air with the purge gas to discourage oxidation of the near frictionless diamond-like carbon coatings; continuing to supply the purge gas to the bearing cavity; and operating the compressor while supplying the purge gas to the bearing cavity, such that the purge gas flows from the bearing cavity to the rotor to prevent the ingress of air into the bearing cavity. 19. The method of claim 18 , wherein the purge gas has a nitrogen content of at least 95%. 20. The method of claim 19 , further comprising drying the compressed air prior to generating the purge gas, and supplying the purge gas to the bearing cavity as a dry purge gas. 21. The method of claim 19 , further comprising increasing the pressure of the purge gas using a gas amplifier powered by the compressed air.