UV-LED collimated radiation photoreactor

What is claimed is: 1. An ultraviolet (UV) reactor for irradiating a flow of fluid with UV radiation, the reactor comprising: a fluid conduit comprising a fluid inlet and a fluid outlet and a longitudinally extending fluid flow channel located between the inlet and the outlet, the fluid flow channel extending in a longitudinal direction from the inlet to the outlet for permitting a flow of fluid therethrough in a principal fluid flow direction parallel with the longitudinal direction, the fluid flow channel having a transverse cross section shaped to permit fluid flow throughout the cross-section including along a central axis extending in the longitudinal direction at a center of the cross section; at least one UV light emitting diode (UV-LED) having a principal irradiation axis; and a radiation-focussing element positioned in a radiation path of radiation emitted from the at least one UV-LED, the radiation-focussing element consisting of: a converging lens located to directly receive the radiation emitted from the at least one UV-LED; and a collimating lens located to directly receive radiation transmitted through the converging lens; the converging lens shaped for collecting the radiation emitted from the at least one UV-LED and for directing the radiation transmitted through the converging lens to impinge directly on the collimating lens; the collimating lens shaped for collecting the radiation transmitted through the converging lens and directing radiation transmitted through the collimating lens in the longitudinal direction, thereby directing the radiation transmitted through the collimating lens to impinge on the fluid flowing in the longitudinally extending fluid flow channel. 2. A UV reactor according to claim 1 , wherein the collimating lens and the converging lens are at least one of shaped and positioned, such that the entire transverse cross-section of the longitudinally extending fluid flow channel is substantially irradiated with the radiation transmitted through the collimating lens. 3. A UV reactor according to claim 1 , wherein the converging lens and the collimating lens are shaped such that the radiation transmitted through the collimating lens is substantially collimated in a collimation direction and the at least one UV-LED and the radiation focussing element are oriented such that the collimation direction is opposite to the principal fluid flow direction. 4. A UV reactor according to claim 1 wherein the converging lens and the collimating lens are shaped such that the radiation transmitted through the collimating lens is substantially collimated in a collimation direction and the at least one UV-LED and the radiation focussing element are oriented such that the collimation direction is the same as the principal fluid flow direction. 5. A UV reactor according to claim 1 comprising: at least one second UV light emitting diode (UV-LED); and a second radiation-focussing element positioned in a radiation path of second radiation emitted from the at least one second UV-LED, the second radiation-focussing element consisting of a second converging lens and a second collimating lens, the second converging and second collimating lenses shaped for collecting the second radiation emitted from the at least one second UV-LED and for directing the second radiation in the longitudinal direction to impinge on the fluid flowing in the longitudinally extending fluid flow channel. 6. A UV reactor according to claim 1 , wherein the fluid conduit comprises a plurality of stacked fluid flow channels, each of the stacked flow fluid channels extending in a corresponding longitudinal direction for permitting a flow of fluid therethrough in the principal fluid flow direction, each of the stacked fluid flow channels having a corresponding transverse cross section shaped to permit fluid flow throughout the corresponding cross-section including along a corresponding central axis extending in the longitudinal direction at a center of the corresponding cross section. 7. A UV reactor according to claim 6 comprising, for each of the stacked fluid flow channels: at least one corresponding UV light emitting diode (UV-LED); and a corresponding radiation-focussing element positioned in a radiation path of radiation emitted from the at least one UV-LED, the corresponding radiation-focussing element consisting of a converging lens and a collimating lens, the converging and collimating lenses shaped for collecting the radiation emitted from the at least one corresponding UV-LED and for directing the collected radiation in the longitudinal direction to impinge on the fluid flowing in the stacked fluid flow channel. 8. A UV reactor according to claim 7 , wherein, for each of the stacked fluid flow channels, the converging lens and the collimating lens are shaped such that the radiation transmitted through the collimating lens is substantially collimated in a collimation direction and the at least one corresponding UV-LED and the corresponding radiation focussing element are oriented such that the collimation direction is opposite to the principal fluid flow direction. 9. A UV reactor according to claim 7 , wherein, for each of the stacked fluid flow channels, the converging lens and the collimating lens are shaped such that the radiation transmitted through the collimating lens is substantially collimated in a collimation direction and the at least one corresponding UV-LED and the corresponding radiation focussing element are oriented such that the collimation direction is the same as the principal fluid flow direction. 10. A UV reactor according to claim 7 , wherein: for one or more of the stacked fluid flow channels, the converging lens and the collimating lens are shaped such that the radiation transmitted through the collimating lens is collimated in a collimation direction and the at least one corresponding UV-LED and the corresponding radiation focussing element are oriented such that the collimation direction is opposite to the principal fluid flow direction; and for one or more of the stacked fluid flow channels, the converging lens and the collimating lens are shaped such that the radiation transmitted through the collimating lens is collimated in a collimation direction and the at least one corresponding UV-LED and the corresponding radiation focussing element are oriented such that the collimation direction is the same as the principal fluid flow direction. 11. A UV reactor according to claim 7 wherein the stacked fluid flow channels are fluidly connected in series to provide a serpentine fluid flow path between the inlet and the outlet of the fluid conduit. 12. A UV reactor according to claim 1 , further comprising at least one photocatalyst supported in the fluid conduit. 13. A UV reactor according to claim 1 , wherein the fluid conduit comprises at least one static mixer or at least one vortex generator. 14. A UV reactor according to claim 1 , wherein each UV-LED is automatically turned on and off by a signal. 15. A UV reactor according to claim 1 , further comprising a chemical reagent added to the fluid conduit. 16. A UV reactor according to claim 1 , wherein the at least one UV-LED comprises a plurality of UV-LEDs and each UV-LED of the plurality of UV-LEDs emits radiation at a different wavelength. 17. A UV reactor according to claim 1 , wherein the internal walls of the fluid conduit are made of or internally coated with a material having high UV reflectivity. 18. A method of irradiating a flow of fluid with ultraviolet (UV) radiation, the method com