Tilrotor aircraft having rotary and non rotary flight modes

What is claimed is: 1. A mechanism for transitioning a tiltrotor aircraft between rotary and non-rotary flight modes, the aircraft including a mast and a rotor assembly having a gimballing degree of freedom relative to the mast, the rotor assembly including a plurality of rotor blade assemblies each having a pitching degree of freedom and a folding degree of freedom, the mechanism comprising: a conical ring positioned about the mast, the conical ring having a disengaged position relative to the rotor assembly, enabling the gimballing degree of freedom in the rotary flight mode and an engaged position relative to the rotor assembly, disabling the gimballing degree of freedom in the non-rotary flight mode; a blade stop assembly positioned about the mast, the blade stop assembly including a plurality of arms having a radially contracted orientation in the rotary flight mode and a radially extended orientation in the non-rotary flight mode; a blade lock assembly operably associated with each rotor blade assembly, each blade lock assembly having a first position, disabling the folding degree of freedom and enabling the pitching degree of freedom of the respective rotor blade assembly in the rotary flight mode and a second position, enabling the folding degree of freedom and disabling the pitching degree of freedom of the respective rotor blade assembly in the non-rotary flight mode; and a swash plate positioned about and operable to rise and fall relative to the mast, the swash plate operable to change the pitch of the rotor blade assemblies in the rotary flight mode and operable to fold the rotor blade assemblies in the non-rotary flight mode. 2. The mechanism as recited in claim 1 , wherein the conical ring further comprises an actuator operably associated with the conical ring to raise and lower the conical ring relative to the mast to transition the conical ring between the engaged and disengaged positions. 3. The mechanism as recited in claim 2 , wherein the actuator further comprises an actuation ring positioned about the mast, the actuation ring operable to raise and lower the conical ring relative to the mast. 4. The mechanism as recited in claim 1 , wherein the blade stop assembly further comprises an actuator operably associated with the arms to transition the arms between the radially contracted orientation and the radially extended orientation. 5. The mechanism as recited in claim 4 , wherein the actuator further comprises an actuation ring positioned about the mast, the actuation ring operable to transition the arms between the radially contracted orientation and the radially extended orientation. 6. The mechanism as recited in claim 1 further comprising an actuator that is common to the conical ring and the blade stop assembly such that the conical ring transitions between the disengaged and engaged positions as the arms of the blade stop assembly transition between the radial retracted and radially extended orientations. 7. The mechanism as recited in claim 1 , wherein each rotor blade assembly includes a cuff and a rotor blade pivotably coupled to the cuff and wherein the swash plate is coupled to each cuff by a pitch link and a pitch horn such that rise and fall of the swash plate in the rotary flight mode changes the pitch of the rotor blade assemblies and such that rise and fall of the swash plate in the non-rotary flight mode folds the rotor blades relative to the cuffs. 8. The mechanism as recited in claim 7 , wherein each blade lock assembly further comprises: a crank and a link coupled at a pivot joint, each link rotatably coupled to the respective rotor blade, each crank rotatably coupled to the respective cuff and operable to rotate relative to the respective cuff responsive to rise and fall of the swash plate in the non-rotary flight mode; and a blade lock having a fold lock position securing the pivot joint to the respective cuff and a pitch lock position securing the respective cuff to the respective arm of the blade stop assembly. 9. The mechanism as recited in claim 8 further comprising an actuator operably coupled to each blade lock, each actuator operable to shift the respective blade lock between the fold lock position and the pitch lock position. 10. The mechanism as recited in claim 9 , wherein each blade lock further comprises a pitch lock and a fold lock, the pitch lock rotatably coupled to the respective cuff at an inboard location, the fold lock rotatably coupled to the respective cuff outboard of the pitch lock. 11. The mechanism as recited in claim 10 , wherein each fold lock disables the folding degree of freedom of the respective rotor blade assembly in the rotary flight mode and enables the folding degree of freedom of the respective rotor blade assembly in the non-rotary flight mode. 12. The mechanism as recited in claim 10 , wherein each pitch lock disables the pitching degree of freedom of the respective rotor blade assembly in the non-rotary flight mode and enables the pitching degree of freedom of the respective rotor blade assembly in the rotary flight mode. 13. The mechanism as recited in claim 1 , wherein the aircraft is in the rotary flight mode when the conical ring is in the disengaged position, the arms of the blade stop assembly are in the radially contracted orientation and each of the blade lock assemblies is in the first position and wherein the aircraft is in the non-rotary flight mode when the conical ring is in the engaged position, the arms of the blade stop assembly are in the radially extended orientation and each of the blade lock assemblies is in the second position. 14. A tiltrotor aircraft having rotary and non-rotary flight modes, the aircraft comprising: a mast; a rotor assembly having a gimballing degree of freedom relative to the mast, the rotor assembly including a plurality of rotor blade assemblies each having a pitching degree of freedom and a folding degree of freedom; a conical ring positioned about the mast, the conical ring having a disengaged position relative to the rotor assembly, enabling the gimballing degree of freedom in the rotary flight mode and an engaged position relative to the rotor assembly, disabling the gimballing degree of freedom in the non-rotary flight mode; a blade stop assembly positioned about the mast, the blade stop assembly including a plurality of arms having a radially contracted orientation in the rotary flight mode and a radially extended orientation in the non-rotary flight mode; a blade lock assembly operably associated with each rotor blade assembly, each blade lock assembly having a first position, disabling the folding degree of freedom and enabling the pitching degree of freedom of the respective rotor blade assembly in the rotary flight mode and a second position, enabling the folding degree of freedom and disabling the pitching degree of freedom of the respective rotor blade assembly in the non-rotary flight mode; and a swash plate positioned about and operable to rise and fall relative to the mast, the swash plate operable to change the pitch of the rotor blade assemblies in the rotary flight mode and operable to fold the rotor blade assemblies in the non-rotary flight mode. 15. The aircraft as recited in claim 14 further comprising an engine having a turboshaft mode corresponding to the rotary flight mode of the aircraft and a turbofan mode corresponding to the non-rotary flight mode of the aircraft, the engine providing torque and rotational energy to the mast in the turboshaft mode and providing no torque and rotational energy to the mast in the turbofan mode. 16. The aircraft as r