Tapered sockets for aircraft engine mount assemblies

What is claimed is: 1. An engine mount assembly for coupling an engine to an airframe, the engine mount assembly comprising: a torsion bar coupled between the engine and the airframe, the torsion bar having at least one end including a tapered boss; at least one arm assembly coupling the at least one end of the torsion bar to the engine, the at least one arm assembly including an end bell crank having a tapered socket; and a lateral movement control assembly coupled between the torsion bar and the airframe, the torsion bar rotating in response to lateral movement of the engine; wherein the tapered socket of the end bell crank is adapted to receive the tapered boss on the at least one end of the torsion bar to secure the end bell crank to the torsion bar such that the end bell crank rotates with the torsion bar responsive to movements of the engine. 2. The engine mount assembly as recited in claim 1 wherein the tapered boss further comprises a plurality of tapered sides forming a substantially polygonal boss; and wherein the tapered socket further comprises a plurality of tapered sides forming a substantially polygonal socket. 3. The engine mount assembly as recited in claim 1 wherein the tapered boss further comprises first, second and third tapered sides forming a substantially triangular boss; and wherein the tapered socket further comprises first, second and third tapered sides forming a substantially triangular socket. 4. The engine mount assembly as recited in claim 1 wherein the tapered boss further comprises a plurality of tapered sides each having the same taper angle; and wherein the tapered socket further comprises a plurality of tapered sides each having the same taper angle. 5. The engine mount assembly as recited in claim 4 wherein the plurality of tapered sides of the tapered boss have substantially the same taper angle as the plurality of tapered sides of the tapered socket. 6. The engine mount assembly as recited in claim 1 wherein the tapered boss further comprises a plurality of tapered sides; wherein the tapered socket further comprises a plurality of tapered sides; and wherein each of the plurality of tapered sides of the tapered boss is adapted to abut one of the tapered sides of the tapered socket. 7. The engine mount assembly as recited in claim 1 further comprising: a fastener; wherein the tapered boss further comprises a receiving hole; wherein the tapered socket further comprises an aperture; and wherein the fastener is insertable into the aperture and the receiving hole to tighten the tapered socket against the tapered boss. 8. The engine mount assembly as recited in claim 7 wherein the receiving hole further comprises a threaded receiving hole; and wherein the fastener further comprises a screw threadable into the receiving hole. 9. The engine mount assembly as recited in claim 1 wherein the end bell crank further comprises a bell crank arm having a distal end forming a bell crank arm socket. 10. The engine mount assembly as recited in claim 9 wherein the at least one arm assembly further comprises a linkage having first and second ends; wherein the bell crank arm socket is adapted to receive the first end of the linkage; and wherein a bolt is insertable through at least one linkage securing aperture and the first end of the linkage to secure the first end of the linkage within the bell crank arm socket. 11. The engine mount assembly as recited in claim 1 wherein the engine is subject to torsional movement and wherein the end bell crank rotates in response to torsional movement of the engine. 12. The engine mount assembly as recited in claim 1 wherein the at least one arm assembly further comprises: a scissor mount attachable to the engine; and a linkage coupling the scissor mount to the end bell crank. 13. The engine mount assembly as recited in claim 1 wherein the lateral movement control assembly reacts to the rotation of the torsion bar such that lateral movement of the engine is controllable based on a lateral stiffness of the lateral movement control assembly. 14. The engine mount assembly as recited in claim 1 wherein the lateral movement control assembly further comprises: a middle bell crank fixedly coupled to the torsion bar; and a spring coupled to the middle bell crank, the spring having the lateral stiffness to control lateral movement of the engine. 15. A rotorcraft comprising: an airframe; an engine; an engine mount assembly adapted to mount the engine to the airframe, the engine mount assembly including: a torsion bar having at least one end including a tapered boss; at least one arm assembly coupling the at least one end of the torsion bar to the engine, the at least one arm assembly including an end bell crank having a tapered socket; and a lateral movement control assembly coupled between the torsion bar and the airframe, the torsion bar rotating in response to lateral movement of the engine; wherein the tapered socket of the end bell crank is adapted to receive the tapered boss on the at least one end of the torsion bar to secure the end bell crank to the torsion bar such that the end bell crank rotates with the torsion bar responsive to movements of the engine. 16. The rotorcraft as recited in claim 15 wherein the tapered boss further comprises a plurality of tapered sides each having the same taper angle and forming a substantially polygonal boss; wherein the tapered socket further comprises a plurality of tapered sides each having the same taper angle and forming a substantially polygonal socket; and wherein the plurality of tapered sides of the tapered boss have substantially the same taper angle as the plurality of tapered sides of the tapered socket. 17. The rotorcraft as recited in claim 15 wherein the tapered boss further comprises a plurality of tapered sides each having the same taper angle and forming a substantially polygonal boss; wherein the tapered socket further comprises a plurality of tapered sides each having the same taper angle and forming a substantially polygonal socket; and wherein each of the plurality of tapered sides of the tapered boss is adapted to abut one of the tapered sides of the tapered socket. 18. A tiltrotor aircraft having a helicopter mode and an airplane mode, the tiltrotor aircraft comprising: an airframe including a fuselage, a wing and a nacelle; an engine disposed within the nacelle; an engine mount assembly adapted to mount the engine to the airframe, the engine mount assembly including: a torsion bar having at least one end including a tapered boss; at least one arm assembly coupling the at least one end of the torsion bar to the engine, the at least one arm assembly including an end bell crank having a tapered socket; and a lateral movement control assembly coupled between the torsion bar and the airframe, the torsion bar rotating in response to lateral movement of the engine; wherein the tapered socket of the end bell crank is adapted to receive the tapered boss on the at least one end of the torsion bar to secure the end bell crank to the torsion bar such that the end bell crank rotates with the torsion bar responsive to movements of the engine. 19. The tiltrotor aircraft as recited in claim 18 wherein the tapered boss further comprises a plurality of tapered sides each having the same taper angle and forming a substantially polygonal boss; wherein the tapered socket further comprises a plurality of tapered sides each having the same taper angle and forming a substa