Patent Number: 
Section: claims

1. A UV curing device, comprising:two cylindrical reflectors that overlap and are connected to form a union of two at least partially elliptical surfaces, the surfaces united to form top and bottom edges near a midpoint of the otherwise curved union of the surfaces, each cylindrical reflector having a first focus and a second focus, the first foci of the cylindrical reflectors being co-located;at least two UV light sources including a UV light source located at each of the second foci, wherein light reflected from interior surfaces of the at least two cylindrical reflectors is focused at the co-located first foci; anda sample tube axially centered around the co-located first foci and configured to receive a workpiece. 2. The UV curing device of claim 1, wherein the surfaces are at least partially faceted. 3. The UV curing device of claim 2, wherein facets of the surfaces are flat, and wherein a plurality of the facets are joined at corners thereof to form each surface. 4. The UV curing device of claim 2, wherein the facets of the surfaces are curved. 5. The UV curing device of claim 1, wherein intensities and bulb types of the two light sources are varied independently. 6. The UV curing device of claim 1, wherein each UV light source comprises a plurality of semiconductor devices, with each semiconductor device disposed in a respective micro-reflector. 7. The UV curing device of claim 1, wherein each UV light source comprises an array of semiconductor devices disposed in a macro-reflector. 8. The UV curing device of claim 1, further comprising inlet and outlet piping connections through which cooling fluid may circulate. 9. The UV curing device of claim 1, wherein the device does not include any back reflectors or reflective surfaces, other than the interior surfaces of the cylindrical reflectors, for directing the light onto the workpiece. 10. A method of UV curing an optical fiber, comprising:drawing the optical fiber from a preform;coating the optical fiber with a UV-curable coating or polymer system;pulling the optical fiber through a sample tube of a UV curing device, the sample tube centered around a co-located focus of at least two elliptic cylindrical reflectors that overlap and are connected to form a union of two partial elliptic surfaces, the surfaces united to form top and bottom edges near a midpoint of the otherwise curved union of the surfaces; andUV curing the optical fiber by directing UV light onto a surface of the optical fiber at the co-located focus. 11. The method of claim 10, further comprising:after UV curing the optical fiber, coating the optical fiber with an additional UV-curable coating or polymer system, pulling the optical fiber through the sample tube of the UV curing device, and UV curing the optical fiber again by directing UV light onto the surface of the optical fiber at the co-located focus. 12. The method of claim 11, wherein different temperatures, coating viscosities, and/or coating methods are used for different coating stages. 13. The method of claim 11, wherein different light intensities, exposure times, and/or wavelength spectra are used for different UV curing stages. 14. The method of claim 11, wherein coating the optical fiber with a UV-curable coating or polymer system comprises coating the optical fiber with an inner layer, and wherein coating the optical fiber with an additional UV-curable coating or polymer system comprises coating the optical fiber with an outer layer, the outer layer stiffer than the inner layer. 15. The method of claim 14, wherein the inner and outer layers comprise a polymer system comprising initiators, monomers, and oligomers. 16. The method of claim 11, further comprising pulling the optical fiber through a sample tube of each of a plurality of UV curing devices arranged linearly in series, the sample tube of each UV curing device centered around a co-located focus of at least two elliptic cylindrical reflectors that overlap and are connected to form a union of two partial elliptic surfaces, the surfaces united to form top and bottom edges near a midpoint of the otherwise curved union of the surfaces, each UV curing device curing the optical fiber by directing UV light onto the surface of the optical fiber at the co-located focus. 17. The method of claim 15, wherein a number of UV curing devices arranged in series is based on the linear speed at which the optical fiber is pulled. 18. A photoreactive system for UV curing comprising,a power supply;a cooling subsystem; anda plurality of UV curing devices arranged in series, each UV curing device comprising coupling optics including least two elliptic cylindrical reflectors that overlap and are connected to form a union of two partial elliptic surfaces, the surfaces united to form top and bottom edges near a midpoint of the otherwise curved union of the surfaces, each elliptic cylindrical reflector having a first focus and a second focus, the first foci of the elliptic cylindrical reflectors being co-located, each UV curing device further comprising at least two UV light sources including a UV light source located substantially at each of the second foci of the elliptic cylindrical reflectors; anda sample tube axially centered around the co-located first foci and configured to receive a workpiece. 19. The system of claim 18, further comprising mounting brackets by which a housing of each UV light source may attach to a reflector assembly baseplate which is connected to reflector assembly faceplates, the reflector assembly faceplates mechanically fastened to either end of each elliptic cylindrical reflector, and the sample tube mechanically fastened to the reflector assembly faceplates. 20. The system of claim 19, wherein each reflector assembly faceplate includes an alignment mechanism for adjusting an alignment and/or position of the sample tube.