Gas cooling method for can forming

What is claimed is: 1. A cooling gas system for a can bodymaker tool pack, the can bodymaker tool pack having a reciprocating ram and a die pack, the ram having a punch mounted thereon, the die pack having at least one die ring with an opening sized to allow the punch to pass therethrough, the punch structured to axially pass through the die pack with a metallic cup on an end thereof during a forming stroke, wherein the cup is formed into a can while passing through the die ring, the can being stripped from the punch as the ram moves reversely through the die ring during a return stroke, the cooling gas system comprising: a compressed gas system structured to deliver a gas to at least one nozzle assembly; and at least one nozzle assembly disposed adjacent to the die ring, the at least one nozzle assembly structured to direct a gas toward at least one of the punch and the at least one die ring. 2. The cooling gas system of claim 1 wherein: the compressed gas system structured to deliver a compressed gas to the at least one nozzle assembly; and wherein the compressed gas expands to about atmospheric pressure as it passes through the at least one nozzle assembly. 3. The cooling gas system of claim 2 wherein the compressed gas system delivers a compressed gas to the nozzle assembly at a pressure of between about 10 and 50 bars. 4. The cooling gas system of claim 2 wherein the nozzle assembly directs a gas toward the at least one of the punch and the at least one die ring at a temperature of between about −75 and −200 degrees C. 5. The cooling gas system of claim 2 wherein the punch has a generally cylindrical body and wherein the at least one nozzle assembly is structured to direct the gas in a path corresponding to the punch cylindrical body. 6. The cooling gas system of claim 2 wherein the at least one nozzle assembly is structured to direct the gas in a path corresponding to the contour of the die ring. 7. The cooling gas system of claim 2 wherein the at least one nozzle assembly is structured to direct the gas in a laminar flow. 8. The cooling gas system of claim 2 wherein: said at least one nozzle assembly includes a body; the at least one nozzle assembly includes a flow direction assembly; and wherein said flow direction assembly is spaced from said at least one nozzle assembly body. 9. The cooling gas system of claim 8 wherein the flow direction assembly is structured to create a spiral gas flow path, the spiral gas flow path corresponding to one of the punch cylindrical body or the contour of the die ring. 10. The cooling gas system of claim 8 wherein the flow direction assembly is a turbulator. 11. The cooling gas system of claim 1 wherein the compressed gas system does not compress the gas to a supercritical state. 12. The cooling gas system of claim 1 wherein: the compressed gas system includes a liquid system; and the liquid system structured to apply a liquid to at least one of the punch, the at least one die ring, and the cup or can. 13. The cooling gas system of claim 12 wherein the liquid system is structured to apply at least one of water, a lubricant, and a lubricant in water emulsion. 14. The cooling gas system of claim 1 wherein the compressed gas system and at least one nozzle assembly are structured to not apply a liquid to the surface of the punch or the at least one die ring. 15. The cooling gas system of claim 1 wherein the compressed gas system and at least one nozzle assembly are structured to apply a limited amount of liquid to the surface of the punch or the at least one die ring. 16. A can bodymaker comprising: a die pack, the die pack having at least one die ring with an opening sized to allow a punch to pass therethrough; a reciprocating ram; a punch, the punch mounted on the ram; the ram positioned so that the punch reciprocates through the die pack; a cooling gas system including a compressed gas system and at least one nozzle assembly; the compressed gas system structured to deliver a gas to the at least one nozzle assembly; and the at least one nozzle assembly disposed adjacent to the die ring, the at least one nozzle assembly structured to direct a gas toward at least one of the punch and the at least one die ring. 17. The can bodymaker of claim 16 wherein: the compressed gas system structured to deliver a compressed gas to the at least one nozzle assembly; and wherein the compressed gas expands to about atmospheric pressure as it passes through the at least one nozzle assembly. 18. The can bodymaker of claim 17 wherein the punch has a generally cylindrical body and wherein the at least one nozzle assembly is structured to direct the gas in a path corresponding to the punch cylindrical body. 19. The can bodymaker of claim 17 wherein the at least one nozzle assembly is structured to direct the gas in a path corresponding to the contour of the die ring. 20. The can bodymaker of claim 16 wherein the compressed gas system does not compress the gas to a supercritical state. 21. The can bodymaker of claim 16 wherein: the compressed gas system includes a liquid system; and the liquid system structured to apply a liquid to at least one of the punch, the at least one die ring, and the cup or can. 22. The can bodymaker of claim 21 wherein the liquid system is structured to apply at least one of water, a lubricant, and a lubricant in water emulsion. 23. The can bodymaker of claim 16 wherein the cooling gas system is structured to not apply a liquid to the surface of the punch or the at least one die ring. 24. The can bodymaker of claim 16 wherein the cooling gas system is structured to apply a limited amount of liquid to the surface of the punch or the at least one die ring.