Electromechanical brake caliper with rolling friction motion converters

I claim: 1. A piston assembly for a brake comprising: a piston having a piston cavity; a spindle configured to be rotatable; a ball screw assembly located at least partially within the piston cavity, the ball screw assembly comprising a screw shaft screw-coupled with the spindle and a ball nut operably coupled with the screw shaft through balls; and a torsion spring configured to provide a preload torque between the screw shaft and the ball nut of the ball screw assembly to resist relative rotation of the screw shaft of the ball screw assembly with respect to the ball nut of the ball screw assembly so that the screw shaft and the ball nut of the ball screw assembly are linearly movable in response to rotation of the spindle, wherein the screw shaft of the ball screw assembly is relatively rotatable with respect to the ball nut of the ball screw assembly in response to the rotation of the spindle when a torque applied to the torsion spring overcomes the preload torque of the torsion spring, wherein clearance is provided between a screwed-coupled portion of the spindle screwed-coupled with the screw shaft and a screwed-coupled portion of the screw shaft screw-coupled with the spindle so that an axis of the spindle is angularly articulatable in a direction perpendicular to an axis of the screw shaft of the ball screw assembly. 2. The piston assembly of claim 1 , wherein the torsion spring is configured to delay the relative rotation of the screw shaft and the ball nut of the ball screw assembly upon the rotation of the spindle in relation to the piston upon application of the brake. 3. The piston assembly of claim 1 further comprising a thrust bearing configured to transfer force from the spindle to a caliper housing. 4. The piston assembly of claim 1 , wherein an interior surface of the screw shaft has less than two threads of engagement with the spindle. 5. The piston assembly of claim 1 , wherein the torque applied to the torsion spring includes a friction torque between the spindle and the screw shaft of the ball screw assembly. 6. The piston assembly of claim 1 , wherein the torsion spring is disposed between the screw shaft of the ball screw assembly and a cap of the ball nut of the ball screw assembly. 7. The piston assembly of claim 1 , wherein one end of the torsion spring is coupled with a cap of the ball nut of the ball screw assembly and another end of the torsion spring is coupled with the screw shaft of the ball screw assembly. 8. The piston assembly of claim 1 , wherein the screw shaft comprises a travel stop operably associated with the one or more stops to limit the rotatable amount of the relative rotation of the screw shaft with respect to the ball nut. 9. The piston assembly of claim 8 , wherein the one or more stops are included in the ball nut or a cap fixed to the ball nut of the ball screw assembly and the travel stop is included in the screw shaft of the ball screw assembly. 10. The piston assembly of claim 1 , wherein an interior surface of the screw shaft of the ball screw assembly has a first surface facing and spaced apart from an exterior surface of the spindle and a second surface screwed-coupled with the spindle. 11. The piston assembly of claim 10 , wherein an inner diameter of the first surface of the screw shaft of the ball screw assembly spaced apart from the exterior surface of the spindle is greater than an inner diameter of the second surface of the screw shaft of the ball screw assembly screw-coupled with the spindle. 12. The piston assembly of claim 1 , wherein the torsion spring and at least a part of the screw shaft are positioned inside an inner space of the ball nut formed by an inside surface of the ball nut. 13. The piston assembly of claim 1 , further comprising: two stops configured to limit a rotatable amount of the relative rotation of the screw shaft of the ball screw assembly with respect to the ball nut of the ball screw assembly; and a travel stop configured to be movable between the two stops and operably associated with the two stops to limit the rotatable amount of the relative rotation of the screw shaft with respect to the ball nut. 14. A brake system comprising: the piston assembly of claim 1 ; a caliper housing having a piston cylinder with the piston assembly located at least partially therein; first and second brake pads positioned in the caliper housing; a brake disk located between the first and second brake pads; and a motor. 15. The brake system of claim 14 , wherein the motor is in operational communication with the spindle and turns the spindle to apply and release the brake. 16. The brake system of claim 15 , wherein the motor is connected to the spindle through a gear box. 17. A method of applying brakes comprising: actuating the brake system of claim 14 comprising rotating the spindle in a first direction, whereby the screw shaft and the ball nut of the ball screw assembly begin linearly moving to move the piston toward the first brake pad, and after the piston contacts the first brake pad, the screw shaft of the ball screw assembly begins turning to push the first brake pad against the brake disk to create a braking force. 18. A method of releasing brakes comprising: rotating the spindle of the brake system of claim 14 in a second direction, whereby the screw shaft of the ball screw assembly begins turning and releases force being applied to the first brake pad and moves the piston away from the first brake pad, and after the brake force being applied to the first brake pad is released, the screw shaft of the ball screw assembly stops turning and the screw shaft and ball nut of the ball screw assembly begin linearly moving to retract the piston. 19. A piston assembly for a brake comprising: a piston having a piston cavity; a spindle configured to be rotatable; a ball screw assembly located at least partially within the piston cavity, the ball screw assembly comprising a screw shaft screw-coupled with the spindle and a ball nut operably coupled with the screw shaft through balls; and a torsion spring configured to resist relative rotation of the screw shaft with respect to the ball nut so that the screw shaft and the ball nut of the ball screw assembly are linearly movable in response to rotation of the spindle before the piston contacts a brake pad, and the screw shaft of the ball screw assembly is relatively rotatable with respect to the ball nut of the ball screw assembly and the ball nut of the ball screw assembly is linearly movable in response to rotation of the screw shaft of the ball screw assembly after the piston contacts the brake pad, wherein clearance is provided between a screwed-coupled portion of the spindle screwed-coupled with the screw shaft and a screwed-coupled portion of the screw shaft screw-coupled with the spindle so that an axis of the spindle is angularly articulatable in a direction perpendicular to an axis of the screw shaft of the ball screw assembly. 20. A piston assembly for a brake comprising: a piston having a piston cavity; a spindle configured to be rotatable; and a ball screw assembly located at least partially within the piston cavity, the ball screw assembly comprising a screw shaft screw-coupled with the spindle and a ball nut operably coupled with the screw shaft through balls, wherein an interior surface of the screw shaft of the ball screw assembly has a first surface facing and spaced apart from an exterior surface of the spindle and a second surface screwed-coupled with the spind