Actuator upper attachment

What is claimed is: 1. An attachment assembly for connecting an actuator to a frame, the attachment assembly comprising: an outer yoke having a first end and an opposite second end and defining an internal cavity at said second end, the outer yoke having an aperture provided at its second end leading into said cavity; and an inner yoke located within the cavity, said inner yoke having a first end and a second, opposite end; and a tie bar having a ball shaped end, the tie bar extending through said aperture such that the ball shaped end is positioned within the cavity and cannot pass through the aperture, and a spring provided at said first end of said outer yoke that is configured to bias the inner yoke in the direction of said aperture; the attachment assembly further comprising: shearable means for holding the inner yoke in a first position wherein the inner yoke is spaced away from the ball-shaped end of the tie bar; wherein, when the tie bar is loaded against the inner yoke, the shearable means are configured to shear and the spring is configured to move the inner yoke to a second position wherein the inner yoke is in abutment with the ball-shaped end; and the attachment assembly further comprising: latching means that is configured to hold said inner yoke in said second position when said shearable means has been sheared. 2. The attachment assembly of claim 1 , wherein the latching means comprises one or more spring hooks, the, or each, spring hook being mounted to the attachment assembly with a spring biasing the spring hook towards the inner yoke. 3. The attachment assembly of claim 2 , wherein, when the inner yoke is in the second position, the spring of the, or each, spring hook moves the spring hook to abut the first end of the inner yoke to prevent movement of the inner yoke away from the ball-shaped end. 4. The attachment assembly of claim 1 , wherein the shearable means comprise one or more fuse pins. 5. The attachment assembly of claim 4 , wherein each fuse pin extends in a transverse direction and engages with a respective indentation formed in the inner yoke, wherein each indentation is larger in an axial direction than an axial size of the fuse pin, such that a gap is provided between an axial edge of the fuse pin and an edge of the indentation, and such that the inner yoke may be moved against the bias of the spring without shearing the or each fuse pin. 6. The attachment assembly of claim 1 , wherein a sensor is configured to detect movement of the inner yoke away from the first position, and to output a signal indicating that a secondary load path is engaged when the inner yoke moves away from the first position. 7. The attachment assembly of claim 6 , wherein the sensor comprises a sensor portion that abuts a target formed on the inner yoke when the inner yoke is in the first position, and wherein the sensor portion does not abut the target when the inner yoke is in the second position. 8. The attachment assembly of claim 1 , wherein the inner yoke is blocked against rotation relative to the outer yoke. 9. A method of manufacturing an upper attachment of an actuator, the method comprising: providing an outer yoke having a first end and an opposite second end and defining an internal cavity at said second end, the outer yoke having an aperture provided at its second end leading into said cavity; and providing an inner yoke within the cavity, said inner yoke having a first end and a second, opposite end; providing a tie bar having a ball shaped end, the tie bar extending through said aperture such that the ball shaped end is positioned within the cavity and cannot pass through the aperture; providing a spring at said first end of said outer yoke that is configured to bias the inner yoke in the direction of said aperture; providing a shearable means for holding the inner yoke in a first position wherein the inner yoke is spaced away from the ball-shaped end of the tie bar; wherein the shearable means is configured to shear when the tie bar is loaded against the inner yoke, and the spring is configured to move the inner yoke to a second position wherein the inner yoke is in abutment with the ball-shaped end; and further comprising providing latching means that is configured to hold said inner yoke in said second position when said shearable means has been sheared. 10. The method according to claim 9 , wherein the latching means comprises spring hooks that are configured to move and abut the first end of the inner yoke. 11. The method according to claim 9 , further comprising providing a sensor that is configured to sense movement of the inner yoke away from the first position. 12. The method according to claim 9 , wherein the shearable means comprises one or more fuse pins, and the method further comprises positioning each of the one more fuse pins so the it extends in a transverse direction and engages with a respective indentation formed in the inner yoke, wherein each indentation is larger in an axial direction than an axial size of the fuse pin, such that a gap is provided between an axial edge of the fuse pin and an edge of the indentation; the method further comprising providing means for testing the upper attachment, said means comprising the inner yoke being configured to move within the cavity without shearing the or each fuse pin. 13. A method of reducing backlash in an upper attachment of an actuator when a secondary load path is engaged, the method comprising: mounting a ball-shaped end of a tie bar in a cavity of an outer yoke having a first end and an opposite second end, the outer yoke having an aperture provided at its second end connected to said cavity; wherein a movable inner yoke is located within the cavity; biasing the inner yoke towards the aperture; holding the inner yoke in a first position wherein the inner yoke is spaced away from the ball-shaped end of the tie bar by shearable means; shearing the shearable means when the tie bar is loaded against the inner yoke, such that the inner yoke moves to a second position under the bias to a second position wherein the inner yoke is in abutment with the ball-shaped end; latching the inner yoke in the second position. 14. The method according to claim 13 , wherein the step of latching the inner yoke in the second position comprises spring hooks moving to abut a first end of the inner yoke. 15. The method according to claim 13 , comprising sensing, using a sensor, movement of the inner yoke away from the first position.