Bearing for use in sliding head restraint

What is claimed is: 1. A head restraint preassembly comprising: a head restraint including a body and a first and second post extending from the body; a first guide sleeve adapted to engage with the first post; and a second guide sleeve adapted to engage with the second post; wherein the first guide sleeve includes a generally cylindrical sidewall and a plurality of wave structures extending radially from the generally cylindrical sidewall, wherein the first guide sleeve has an initial unassembled radial stiffness, wherein the first guide sleeve is adapted to have an assembled radial stiffness, as measured after the first post is inserted into the first guide sleeve, and wherein the initial unassembled radial stiffness is less than the assembled radial stiffness. 2. The head restraint preassembly according to claim 1 , wherein at least one wave structure of the plurality of wave structures includes at least one feature prior to the first post being inserted into the first guide sleeve, the feature including: an aperture extending through a portion of the at least one wave structure; a portion having a reduced thickness; a dimpled section; a partially disconnected wave structure; or any combination thereof. 3. The head restraint preassembly according to claim 2 , wherein the partially disconnected wave structure comprises a wave structure disconnected from the adjacent undeformed portion of the sidewall along at least two sides of the wave structure. 4. The head restraint preassembly according to claim 2 , wherein the generally cylindrical sidewall has a thickness, T SW , wherein the portion having a reduced thickness has a thickness, T P , and wherein a ratio of T P :T SW is no greater than about 0.99. 5. The head restraint preassembly according to claim 2 , wherein the portion having a reduced thickness is adapted to have a greater radial stiffness after the post is inserted into the guide sleeve. 6. The head restraint preassembly according to claim 2 , wherein the portion having a reduced thickness has an initially unassembled radial stiffness, S 1 , wherein the portion having a reduced thickness has an assembled stiffness after the post is inserted into the guide sleeve, S 2 , and wherein a ratio of S 2 :S 1 is no less than about 1.01. 7. The head restraint preassembly according to claim 1 , wherein the first guide sleeve is adapted to translate relative to the first post upon application of a force of no greater than 30 N. 8. The head restraint preassembly according to claim 1 , wherein the undeformed portion of the sidewall and the plurality of wave structures are of unitary construction. 9. The head restraint preassembly according to claim 1 , wherein the first guide sleeve comprises a composite structure including a metal substrate and a low friction polymer layer. 10. The head restraint preassembly according to claim 9 , wherein the low friction polymer layer comprises a PTFE. 11. The head restraint preassembly according to claim 1 , wherein the first guide sleeve has a radial stiffness of no less than 2,000 N/mm, and wherein the first sleeve is adapted to translate along the first post upon application of a force of no greater than 30 N. 12. The head restraint preassembly according to claim 1 , wherein each of the plurality of wave structures protrude radially inward toward a central axis of the first guide sleeve. 13. The head restraint preassembly according to claim 1 , wherein the first guide sleeve has an axial length, L GS , and wherein: each wave structure of the first guide sleeve has an axial length, L WS , that is no less than 0.25 L GS ; the plurality of wave structures define at least two circumferentially extending rows around the first guide sleeve; or a combination thereof. 14. The head restraint preassembly according to claim 1 , wherein the head restrain assembly further comprises a locking mechanism adapted to selectively secure the first post relative to the first guide sleeve, wherein the locking mechanism is detachably coupled to the generally cylindrical sidewall. 15. The head restraint preassembly according to claim 14 , wherein the locking mechanism comprises a different material than the generally cylindrical sidewall and wherein the locking mechanism is rotatably coupled to the first guide sleeve. 16. The head restraint preassembly according to claim 14 , wherein the first post has an adjustment length, and wherein the locking mechanism is adapted to secure the first guide sleeve at any location along the adjustment length. 17. The head restraint preassembly according to claim 1 , wherein the first guide sleeve has an initial unassembled radial stiffness of less than about 1000 N/mm, and wherein the guide sleeve is adapted to have an assembled radial stiffness, as measured after the post is inserted into the first guide sleeve, of no less than about 1000 N/mm. 18. The head restraint preassembly according to claim 1 , wherein the first guide sleeve has an initial inner diameter, D I , as measured along a best fit circle tangent to an innermost surface of the guide sleeve before the post is inserted into the guide sleeve, wherein the guide sleeve has an operational diameter, D O , as measured along a best fit circle tangent to an innermost surface of the guide sleeve after the post is inserted into the guide sleeve, and wherein D I is greater than D O . 19. The head restraint preassembly according to claim 18 , wherein a ratio of D O :D I is no less than about 1.0. 20. The head restraint preassembly according to claim 1 , wherein the first guide sleeve is adapted to absorb an angular misalignment with the post while maintaining the assembled radial stiffness, the angular misalignment defined by a misalignment angle, A M , as measured by the angle between the post and a central axis of the guide sleeve, and wherein the guide sleeve is adapted to absorb an A M up to about 10.