Apparatuses for screen testing an optical fiber and methods for using the same

What is claimed is: 1. An apparatus for screen testing an optical fiber, the apparatus comprising: a fiber conveyance pathway; a capstan having an outer circumference and a fiber contact region extending around the outer circumference, the fiber contact region having an overall durometer hardness of less than or equal to 40 Shore A, wherein the capstan is positioned adjacent to the fiber conveyance pathway such that when the optical fiber is directed over the fiber conveyance pathway, the optical fiber engages with the fiber contact region of the capstan; and a pinch belt positioned adjacent to the fiber conveyance pathway such that the fiber conveyance pathway extends between at least a portion of the pinch belt and the fiber contact region of the capstan, wherein the pinch belt is engageable with the fiber contact region of the capstan such that, when the optical fiber is directed over the fiber conveyance pathway, the optical fiber is impinged between the pinch belt and the fiber contact region of the capstan. 2. The apparatus for screen testing an optical fiber of claim 1 wherein the fiber contact region comprises an inner layer of resilient material having a durometer hardness of less than or equal to 35 Shore A. 3. The apparatus for screen testing an optical fiber of claim 2 , wherein the inner layer of resilient material has a shear modulus and a compressive modulus of less than or equal to 1 MPa. 4. The apparatus for screen testing an optical fiber of claim 2 , wherein the fiber contact region further comprises an outer layer positioned over the inner layer of resilient material, the outer layer having a durometer hardness of less than or equal to 90 Shore A. 5. The apparatus for screen testing an optical fiber of claim 4 , wherein the outer layer has a durometer hardness greater than or equal to 55 Shore A and less than or equal to 90 Shore A. 6. The apparatus for screen testing an optical fiber of claim 4 , wherein the outer layer has a thickness greater than or equal to 10 microns and less than or equal to 300 microns. 7. The apparatus for screen testing an optical fiber of claim 4 , wherein the fiber contact region further comprises a base layer positioned beneath the inner layer of resilient material, wherein the base layer is bonded to the inner layer of resilient material, the base layer having a durometer hardness of less than or equal to 90 Shore A. 8. The apparatus for screen testing an optical fiber of claim 2 , wherein a compressive modulus and a shear modulus of the fiber contact region is substantially the same as a compressive modulus and a shear modulus of a primary coating of the optical fiber directed over the fiber conveyance pathway. 9. The apparatus for screen testing an optical fiber of claim 1 , wherein the capstan further comprises a channel extending radially inward from the outer circumference of the capstan, and the fiber contact region comprises an outer layer positioned over the channel of the capstan, the outer layer covering the channel to form an enclosed chamber on the capstan. 10. The apparatus for screen testing an optical fiber of claim 9 , wherein the fiber contact region further comprises an inner layer of resilient material having a durometer hardness of less than or equal to 35 Shore A, the inner layer of resilient material positioned within the channel of the capstan beneath the outer layer. 11. The apparatus for screen testing an optical fiber of claim 10 , wherein the capstan further comprises at least one cog positioned within the channel. 12. The apparatus for screen testing an optical fiber of claim 10 , wherein the channel of the capstan is tapered, such that a width of the channel is narrower at the outer circumference of the capstan than at a position radially inward from the outer circumference. 13. The apparatus for screen testing an optical fiber of claim 10 , wherein vacuum suction is utilized to retain the inner layer of resilient material in the channel of the capstan. 14. The apparatus for screen testing an optical fiber of claim 9 , wherein the enclosed chamber is pressurized such that the chamber exerts a force on the outer layer. 15. The apparatus for screen testing an optical fiber of claim 9 , wherein the fiber contact region has a width that is less than 10 times a diameter of the optical fiber directed over the fiber conveyance pathway. 16. An apparatus for screen testing an optical fiber, the apparatus comprising: a fiber conveyance pathway; a capstan having an outer circumference and a fiber contact region extending around the outer circumference, the fiber contact region having an overall durometer hardness of less than or equal to 40 Shore A, the fiber contact region comprising; an inner layer of resilient material positioned on the outer circumference of the capstan; an outer layer of wear-resistant material positioned over the inner layer of resilient material, the outer layer of wear-resistant material having a durometer hardness of less than or equal to 90 Shore A; and a pinch belt positioned adjacent to the fiber conveyance pathway such that the fiber conveyance pathway extends between at least a portion of the pinch belt and the fiber contact region of the capstan, wherein the pinch belt is engageable with the fiber contact region of the capstan such that, when the optical fiber directed over the fiber conveyance pathway, the optical fiber is impinged between the pinch belt and the fiber contact region of the capstan. 17. The apparatus for screen testing an optical fiber of claim 16 , wherein the inner layer of resilient material has a shear modulus and a compressive modulus of less than or equal to 1 MPa. 18. The apparatus for screen testing an optical fiber of claim 16 , wherein the outer layer of wear-resistant material has a thickness greater than or equal to 10 microns and less than or equal to 300 microns. 19. The apparatus for screen testing an optical fiber of claim 16 , wherein the capstan further comprises a channel extending radially inward from the outer circumference of the capstan, wherein the inner layer of resilient material positioned within the channel beneath the outer layer of wear-resistant material, and the outer layer of wear-resistant material covering the channel to form an enclosed chamber on the capstan.