Rotating machine having magnetically actuated pistons

What is claimed is: 1. A rotating machine ( 10 ), comprising: a stator ( 18 ) defining a circumference ( 148 ); a plurality of first magnet arrays ( 67 A, 67 B, 68 A, 68 B) comprised of a plurality of first discrete magnets ( 160 , 162 ) arranged around the circumference ( 148 ) of the stator ( 18 ) in a first magnetic pattern; a rotor ( 20 ) rotatable about an axis of rotation and defining a main body ( 36 ), wherein the main body ( 36 ) defines a first passageway ( 32 ); and a first piston ( 26 ) including a plurality of first magnetic elements ( 150 , 152 ), wherein the first piston ( 26 ) and the first passageway ( 32 ) of the rotor ( 20 ) define a piston-cylinder assembly, and wherein the plurality of first discrete magnets ( 160 , 162 ) are arranged in the first magnetic pattern and are positioned to interact with the first magnetic elements ( 150 , 152 ) of the first piston ( 26 ) to create a first magnetic force as the rotor ( 20 ) rotates about the axis of rotation, the first magnetic force representing a first amount of force required to actuate the first piston ( 26 ) within the first passageway ( 32 ) of the rotor ( 20 ). 2. The rotating machine ( 10 ) of claim 1 , comprising a second piston ( 30 ) including a plurality of second magnetic elements ( 150 , 152 ), the second piston ( 26 ) actuated within a second passageway ( 34 ) defined by the main body ( 36 ) of the rotor ( 20 ), wherein the stator ( 18 ) includes a plurality of second magnet arrays ( 65 A, 65 B, 66 A, 66 B) comprised of a plurality of second discrete magnets ( 164 , 166 ). 3. The rotating machine ( 10 ) of claim 2 , wherein the plurality of second discrete magnets ( 164 , 166 ) are positioned to interact with the second magnetic elements ( 150 , 152 ) of the second piston ( 30 ) to create a second magnetic force as the rotor rotates about the axis of rotation, the second magnetic force representing a second amount of force required to actuate the second piston ( 30 ) within the second passageway ( 34 ) of the rotor ( 20 ). 4. The rotating machine ( 10 ) of claim 1 , wherein the plurality of first discrete magnets ( 160 , 162 ) define a first direction of magnetization that is opposite to a second direction of magnetization defined by the first magnetic elements ( 150 , 152 ) of the first piston ( 26 ). 5. The rotating machine ( 10 ) of claim 1 , wherein the plurality of first discrete magnets ( 160 , 162 ) comprise ferromagnetic bars ( 167 , 168 ), and the first magnetic elements ( 150 , 152 ) of the first piston ( 26 ) are permanent magnets. 6. The rotating machine ( 10 ) of claim 1 , wherein the plurality of first discrete magnets ( 160 , 162 ) are permanent magnets and the first magnetic elements ( 150 , 152 ) of the first piston ( 26 ) are ferromagnetic bars ( 250 , 252 ). 7. The rotating machine ( 10 ) of claim 1 , wherein the rotating machine ( 10 ) is a Stirling engine including four stages of operation. 8. The rotating machine ( 10 ) of claim 7 , wherein the first magnetic force is configured to actuate the first piston ( 26 ) into one of the four stages of operation of the Stirling engine. 9. The rotating machine ( 10 ) of claim 1 , wherein the rotating machine is a cryocooler employing a Stirling cycle, the cryocooler providing cooling to a load ( 50 ). 10. The rotating machine ( 10 ) of claim 1 , wherein the first piston ( 26 ) is coupled to the rotor ( 20 ) by a bearing ( 70 ). 11. The rotating machine ( 10 ) of claim 10 , wherein the bearing ( 70 ) is selected from the group consisting of: a flexure bearing, a gas bearing, a slide bearing, and a linear ball bearing. 12. The rotating machine ( 10 ) of claim 1 , wherein the first piston ( 26 ) is oriented within the first passageway ( 32 ) in a direction that is substantially perpendicular to the axis of rotation of the rotor ( 20 ). 13. The rotating machine ( 10 ) of claim 1 , wherein the first piston ( 226 ) is actuated in a direction substantially parallel to the axis of rotation of the rotor ( 20 ). 14. The rotating machine ( 10 ) of claim 1 , wherein the first magnetic elements ( 150 , 152 ) define a direction of magnetization that is substantially perpendicular to the axis of rotation of the rotor ( 20 ). 15. The rotating machine ( 10 ) of claim 1 , wherein the first magnetic elements ( 150 , 152 ) define a direction of magnetization that is substantially parallel to the axis of rotation of the rotor ( 20 ). 16. The rotating machine ( 10 ) of claim 1 , comprising a regenerator ( 24 ) positioned about the axis of rotation of the rotor ( 20 ). 17. The rotating machine ( 10 ) of claim 1 , comprising a first regenerator ( 24 A) and a second regenerator ( 24 B), wherein the first regenerator ( 24 A) is positioned at a first side ( 302 ) of the rotor ( 20 ) and the second regenerator ( 24 B) is positioned at a second side ( 302 ) of the rotor ( 20 ) that opposes the first side ( 302 ). 18. A method of actuating a first piston ( 26 ) within a first passageway ( 32 ) of a rotor ( 20 ), wherein the rotor ( 20 ) is part of a rotating machine ( 10 ), the method comprising: rotating the rotor ( 20 ) about an axis of rotation, wherein the rotor ( 20 ) is surrounded by a stator ( 18 ) that defines a circumference ( 148 ), and wherein a plurality of first magnet arrays ( 67 A, 67 B, 68 A, 68 B) are comprised of a plurality of first discrete magnets ( 160 , 162 ) arranged around the circumference ( 148 ) of the stator ( 18 ) in a first magnetic pattern; creating a first magnetic force as the rotor ( 20 ) rotates about the axis of rotation, wherein the first magnetic force is created by an interaction between the plurality of first discrete magnets ( 160 , 162 ) arranged around the circumference ( 148 ) of the stator ( 18 ) and a plurality of first magnetic elements ( 150 , 152 ) of the first piston ( 26 ); and actuating the first piston ( 26 ) within the first passageway ( 32 ) of the rotor ( 20 ) by the first magnetic force, wherein the first piston ( 26 ) and the first passageway ( 32 ) of the rotor ( 20 ) define a piston-cylinder assembly. 19. The method of claim 18 , further comprising creating a second magnetic force as the rotor ( 20 ) rotates about the axis of rotation, wherein the second magnetic force represents a second amount of force required to actuate a second piston ( 30 ) within a second passageway ( 34 ) of the rotor ( 20 ). 20. The method of claim 18 , comprising actuating the first piston ( 26 ) into one of four stages of a Stirling cycle.