Turbine-piston for hydrokinetic torque converter and method of operation

What is claimed is: 1. A torque converter, including a lock-up clutch mechanism, adapted to rotate about an axis, comprising: a torus having an interior torus chamber and comprising an impeller having an impeller perimeter friction surface portion, a stator, and a turbine comprising a reactive turbine-piston having opposite first and second turbine-piston perimeter friction surface portions, said turbine being drivable in a rotary direction around said axis by hydrokinetic energy supplied from said impeller; a casing associated with said torus and providing a casing chamber in variable fluid communication with said torus chamber and axially juxtaposed to said torus chamber on an opposite side of said turbine-piston relative to said torus chamber; and said lock-up clutch mechanism comprising a secondary piston having a secondary-piston perimeter friction surface portion, sealed about a perimeter thereof to said casing, fixed in rotation with respect to said casing, located axially adjacent said turbine piston in said casing chamber, wherein said secondary piston is configured to axially move, in response to an effective fluid pressure increase in said casing chamber relative to said torus chamber, to engage said secondary-piston perimeter friction surface portion with said first turbine-piston perimeter friction surface portion, and further configured to thereafter urge said second turbine-piston perimeter friction surface portion into engagement with said impeller perimeter friction surface portion, thereby eliminating relative rotary motion between said turbine-piston and said impeller. 2. The torque converter as in claim 1 , wherein said secondary piston is fixed in rotation to said casing via splines. 3. The torque converter as in claim 1 , wherein said secondary piston is fixed in rotation to said casing via tabs. 4. The torque converter as in claim 1 , wherein said impeller and turbine-piston perimeter friction surface portions extend in a radial direction. 5. The torque converter as in claim 1 , wherein said first turbine-piston perimeter friction surface portion faces toward said secondary piston, and said second turbine-piston perimeter friction surface portion faces toward said impeller. 6. The torque converter as in claim 5 , wherein said first and second turbine-piston perimeter friction surface portions are clamped between said secondary piston and said impeller perimeter friction surface portion when said lock-up clutch mechanism is engaged. 7. The torque converter as in claim 1 , wherein said impeller perimeter friction surface portion, said first and second turbine-piston perimeter friction surface portions, and said secondary-piston perimeter friction surface portion are radially outward of said torus chamber. 8. A method of operating a torque converter, said method comprising: providing a torus having an interior torus chamber and comprising an impeller having an impeller perimeter friction surface portion, a stator, and a turbine comprising a reactive turbine-piston having opposite first and second turbine-piston perimeter friction surface portions, said turbine being drivable in a rotary direction around said axis by hydrokinetic energy supplied from said impeller; providing a casing associated with said torus and providing a casing chamber in variable fluid communication with said torus chamber and axially juxtaposed to said torus chamber on an opposite side of said turbine-piston relative to said torus chamber; providing a lock-up clutch mechanism comprising a secondary piston having a secondary-piston perimeter friction surface portion, sealed about a perimeter thereof to said casing, fixed in rotation with respect to said casing, and located axially adjacent said turbine-piston in said casing chamber; increasing fluid pressure in said casing chamber relative to said torus chamber to urge said secondary piston toward said turbine-piston and engage the secondary-piston perimeter friction surface portion with said first turbine-piston perimeter friction surface portion; equalizing a rotary speed differential between said secondary piston and said turbine-piston; reducing hydrodynamic pressure within said torus; and further increasing pressure in said casing chamber relative to said torus chamber so as to urge said second turbine-piston perimeter friction surface portion axially, via movement of said secondary piston, toward and into engagement with said impeller perimeter friction surface portion to eliminate relative rotary motion between said turbine-piston and said impeller. 9. The method as in claim 8 , wherein said secondary piston is fixed in rotation to said casing via splines. 10. The method as in claim 8 , wherein said secondary piston is fixed in rotation to said casing via tabs. 11. The method as in claim 8 , wherein said impeller and turbine-piston perimeter friction surface portions extend in a radial direction. 12. The method as in claim 8 , wherein said first turbine-piston perimeter friction surface portion faces toward said secondary piston, and said second turbine-piston perimeter friction surface portion faces toward said impeller. 13. The method as in claim 12 , wherein said first and second turbine-piston perimeter friction surface portions are clamped between said secondary piston and said impeller perimeter friction surface portion when said lock-up clutch mechanism is engaged. 14. The method as in claim 8 , wherein said impeller perimeter friction surface portion, said first and second turbine-piston perimeter friction surface portions, and said secondary-piston perimeter friction surface portion are radially outward of said torus chamber. 15. The torque converter as in claim 2 , wherein said impeller and turbine-piston perimeter friction surface portions extend in a radial direction. 16. The torque converter as in claim 3 , wherein said impeller and turbine-piston perimeter friction surface portions extend in a radial direction. 17. The torque converter as in claim 2 , wherein said first turbine-piston perimeter friction surface portion faces toward said secondary piston, and said second turbine-piston perimeter friction surface portion faces toward said impeller. 18. The torque converter as in claim 3 , wherein said first turbine-piston perimeter friction surface portion faces toward said secondary piston, and said second turbine-piston perimeter friction surface portion faces toward said impeller. 19. The torque converter as in claim 4 , wherein said first turbine-piston perimeter friction surface portion faces toward said secondary piston, and said second turbine-piston perimeter friction surface portion faces toward said impeller.