Hydrokinetic torque coupling device for a motor vehicle

The invention claimed is: 1. A hydrokinetic torque coupling device for a motor vehicle, comprising: a torque input element ( 11 ) intended to be coupled to a crankshaft ( 1 ), a turbine wheel ( 4 ), an impeller wheel ( 3 ) rotationally coupled to the torque input element ( 11 ) and able to hydrokinetically drive the turbine wheel ( 4 ), a torque output element ( 8 ) intended to be coupled to a transmission input shaft ( 2 ), damping means ( 23 , 27 ), clutch means ( 10 ) movable between an engaged position wherein the torque input element ( 11 ) and the torque output element ( 8 ) are rotationally coupled through the damping means ( 23 , 27 ), and a disengaged position wherein the torque input element ( 11 ) and the torque output element ( 8 ) are rotationally coupled through the impeller wheel ( 3 ), the turbine wheel and the damping means ( 23 , 27 ), the damping means ( 23 , 27 ) adapted to act against the rotation of the torque input element ( 11 ) relative to the torque output element ( 8 ), the damping means ( 23 , 27 ) comprising an elastic blade ( 27 ) elastically supported by a supporting member ( 23 ), the elastic blade ( 27 ) being able to bend upon rotation of the torque input element ( 11 ) relative to the torque output element ( 8 ) in the engaged position, the elastic blade transmitting torque through the damping means, the hydrokinetic torque coupling device further comprising a single flange ( 15 ) connecting the turbine wheel ( 4 ) and the supporting member ( 23 ), the elastic blade being connected to the torque output element ( 8 ). 2. The hydrokinetic torque coupling device according to claim 1 , wherein the torque output element comprises a central hub ( 8 ), and wherein the turbine wheel ( 4 ) is mounted to pivot about the central hub ( 8 ). 3. The hydrokinetic torque coupling device according to claim 2 , further comprising a turbine hub ( 17 ) rotationally coupled to the turbine wheel ( 4 ), wherein the turbine hub ( 17 ) is mounted to pivot about the central hub ( 8 ) through a rolling bearing. 4. The hydrokinetic torque coupling device according to claim 3 , wherein the clutch means ( 10 ) comprise at least one piston ( 33 ) rotationally coupled to the flange ( 15 ), and wherein the piston ( 33 ) is moveable relative to the flange ( 10 ) between the engaged position wherein the piston ( 33 ) is rotationally coupled to the torque input element ( 11 ) and the disengaged position wherein the piston ( 33 ) is rotationally uncoupled from the torque input element ( 11 ). 5. The hydrokinetic torque coupling device according to claim 3 , wherein the piston ( 33 ) comprises at least one axially flexible lug ( 39 ) fastened to the piston ( 33 ) through a fastening member ( 25 ) supporting the supporting member ( 23 ). 6. The hydrokinetic torque coupling device according to claim 2 , wherein the clutch means ( 10 ) comprise at least one piston ( 33 ) rotationally coupled to the flange ( 15 ), and wherein the piston ( 33 ) is moveable relative to the flange ( 10 ) between the engaged position wherein the piston ( 33 ) is rotationally coupled to the torque input element ( 11 ) and the disengaged position wherein the piston ( 33 ) is rotationally uncoupled from the torque input element ( 11 ). 7. The hydrokinetic torque coupling device according to claim 2 , wherein the piston ( 33 ) comprises at least one axially flexible lug ( 39 ) fastened to the piston ( 33 ) through a fastening member ( 25 ) supporting the supporting member ( 23 ). 8. The hydrokinetic torque coupling device according to claim 1 , further comprising a reactor ( 5 ), with the impeller wheel ( 3 ) being able to hydrokinetically drive the turbine wheel ( 4 ) through the reactor ( 5 ). 9. A hydrokinetic torque coupling device for a motor vehicle, comprising: a torque input element ( 11 ) intended to be coupled to a crankshaft ( 1 ); a turbine wheel ( 4 ); an impeller wheel ( 3 ) rotationally coupled to the torque input element ( 11 ) and able to hydrokinetically drive the turbine wheel ( 4 ); a torque output element ( 8 ) intended to be coupled to a transmission input shaft ( 2 ); damping means ( 23 , 27 ); clutch means ( 10 ) movable between an engaged position wherein the torque input element ( 11 ) and the torque output element ( 8 ) are rotationally coupled through the damping means ( 23 , 27 ), and a disengaged position wherein the torque input element ( 11 ) and the torque output element ( 8 ) are rotationally coupled through the impeller wheel ( 3 ), the turbine wheel and the damping means ( 23 , 27 ); the damping means ( 23 , 27 ) adapted to act against the rotation of the torque input element ( 11 ) relative to the torque output element ( 8 ), the damping means ( 23 , 27 ) comprising an elastic blade ( 27 ) elastically supported by a supporting member ( 23 ), the elastic blade ( 27 ) being able to bend upon rotation of the torque input element ( 11 ) relative to the torque output element ( 8 ) in the engaged position, the elastic blade transmitting torque through the damping means; the hydrokinetic torque coupling device further comprising a single flange ( 15 ) connecting the turbine wheel ( 4 ) and the supporting member ( 23 ), the elastic blade being connected to the torque output element ( 8 ); the clutch means ( 10 ) comprising at least one piston ( 33 ) rotationally coupled to the flange ( 15 ), the piston ( 33 ) moveable relative to the flange ( 15 ) between the engaged position wherein the piston is rotationally coupled to the torque input element ( 11 ) and the disengaged position wherein the piston is rotationally uncoupled from the torque input element ( 11 ). 10. The hydrokinetic torque coupling device according to claim 9 , wherein the flange ( 15 ) is rotationally coupled to the piston ( 33 ) through at least one protruding part ( 22 ) connected to the flange ( 15 ), respectively to the piston ( 33 ), cooperating, in a form-fitting manner, with at least one recessed part connected to the piston ( 33 ), respectively to the flange ( 15 ), with the protruding and the recessed parts ( 22 ) enabling an axial motion of the piston ( 33 ) relative to the flange ( 15 ) while ensuring the rotational coupling of the piston ( 33 ) and the flange ( 15 ). 11. The hydrokinetic torque coupling device according to claim 10 , wherein the radially external periphery of the flange ( 15 ) comprises a cylindrical rim ( 21 ) which axially extends toward the piston, and wherein the rim ( 21 ) comprises the protruding or recessed part ( 22 ) cooperating with the recessed or protruding part ( 36 ) of the piston ( 33 ) so as to rotationally couple the piston ( 33 ) and the flange ( 15 ). 12. The hydrokinetic torque coupling device according to claim 11 , wherein the supporting member ( 23 ) is mounted on the flange ( 15 ) and is totally radially positioned inside the cylindrical rim ( 21 ) of the flange ( 15 ). 13. The hydrokinetic torque coupling device according to claim 11 , wherein the cylindrical rim ( 21 ) of the flange ( 15 ) comprises at least one opening ( 37 ) or one recession gone through or at least partially accommodating the supporting member ( 23 ). 14. The hydrokinetic torque coupling device according to claim 11 , wherein the piston ( 33 ) comprises at least one axially flexible lug ( 39 ) fastened to the piston ( 33 ) through a fastening member ( 25 ) supporting the supporting member ( 23 ). 15. The hydrokinetic torque coupling device according to claim 10 , wherein the piston ( 33 ) comprises at least one axially flexible lug ( 39 ) fastened to the piston ( 33 ) through a fastening member ( 25 ) supporting th