Solar thermal concentrator and method of forming same

What is claimed is: 1. A concentrator tube extending from a distal end to a proximal end comprising: a trough shaped reflector portion extending between the proximal end and the distal end and defining an upper opening, the reflector portion configured to concentrate light from a source onto an absorber; a light transmissive aperture member closing the upper opening of the trough shaped reflector portion, wherein the reflector portion and the aperture member are formed by rolling a mandrel on an outside surface of a softened glass tube; and the absorber located within the tube; wherein the reflector portion is configured such that substantially any radiation energy emitted from the absorber onto the reflector portion is either directed to the source or directed back to the absorber; and wherein each end of the tube is sealed. 2. The concentrator tube of claim 1 , wherein the tube encloses a volume. 3. The concentrator tube of claim 2 , wherein the volume is substantially evacuated. 4. The concentrator tube of claim 2 , wherein the reflector portion is located on an interior wall of the volume. 5. The concentrator tube of claim 2 , wherein the reflector portion is located outside of the volume. 6. The concentrator tube of claim 1 , wherein the aperture member is less curved than the reflector portion. 7. The concentrator tube of claim 1 , wherein the aperture member is substantially flat. 8. The concentrator tube of claim 1 , wherein the absorber is positioned to accommodate refraction of light entering the concentrator tube through the aperture member. 9. The concentrator tube of claim 1 , wherein the reflector portion is configured to accommodate refraction of light entering the concentrator tube through the aperture member. 10. The concentrator tube of claim 9 , wherein the reflector portion is configured such that edge ray light rays refracted by the aperture member reflect from the reflector portion and contact the absorber. 11. The concentrator tube of claim 1 , wherein the absorber is configured to have a thermal energy transfer fluid flowing therethrough. 12. The concentrator tube of claim 11 , wherein the absorber comprises an input and an output for the thermal energy transfer fluid, and wherein both the input and the output extend through a first end of the concentrator tube. 13. The concentrator tube of claim 11 , wherein the absorber has an end portion located proximal a second end of the concentrator tube, and wherein the end portion is free to move within the tube in response to thermal expansion or contraction. 14. The concentrator tube of claim 11 , wherein the absorber comprises a plurality of minichannels configured to allow flow therethrough of the thermal energy transfer fluid. 15. The concentrator tube of claim 1 , wherein the tube concentrates light incident through the aperture member at angles to an optic axis less than an acceptance angle. 16. The concentrator of claim 15 , wherein the tube concentrates through the aperture member at angles to the optic axis less than the acceptance angle with an optical efficiency greater than 80%. 17. The concentrator of claim 16 , wherein the tube concentrates through the aperture member at angles to the optic axis less than the acceptance angle with an optical efficiency greater than 90%. 18. The concentrator of claim 16 , wherein the tube concentrates through the aperture member at angles to the optic axis less than the acceptance angle with an optical efficiency greater than 95%. 19. The concentrator of claim 16 , wherein the tube concentrates through the aperture member at angles to the optic axis less than the acceptance angle with an optical efficiency greater than 99%. 20. The concentrator of claim 15 , wherein the acceptance angle is greater than 10 degrees. 21. The concentrator of claim 15 , wherein the acceptance angle is greater than 20 degrees. 22. The concentrator of claim 15 , wherein the acceptance angle is greater than 25 degrees. 23. The concentrator of claim 15 , wherein the acceptance angle is greater than 35 degrees. 24. The concentrator tube of claim 1 , wherein the absorber comprises a heat pipe. 25. The concentrator of claim 11 , wherein the absorber comprises a u-shaped tube coupled to an absorber fin. 26. A method of forming a concentrator tube extending from a distal end to a proximal end, comprising: forming a trough shaped reflector portion extending between the proximal end and the distal end and defining an upper opening, the reflector portion configured to concentrate light from a source onto an absorber; forming a light transmissive aperture member closing the upper opening of the trough shaped reflector portion, wherein the reflector portion and the aperture member are formed by rolling a mandrel on an outside surface of a softened glass tube; and positioning the absorber located within the tube; wherein the reflector portion is configured such that substantially any radiation energy emitted from the absorber onto the reflector portion is either directed to the source or directed back to the absorber. 27. The method of claim 26 , further comprising: forming a seal at each end of the tube to form a substantial vacuum within the tube. 28. The method of claim 27 , wherein the seal on at least one end is a metal-to-glass seal. 29. A method comprising: receiving light from a source through a light transmissive aperture member of a concentrator tube extending from a distal end to a proximal end; reflecting and concentrating at least a portion of the light to an absorber of the concentrator tube by a trough shaped reflector portion of the concentrator tube, wherein the reflector portion extends between the proximal end and the distal end, the reflector portion defines an upper opening that is closed by the light transmissive aperture member, and the reflector portion has a cross section of a compound parabolic shape, and wherein the trough shaped reflector portion and the light transmissive aperture member are formed by rolling a mandrel on an outside surface of a softened glass tube; and absorbing the light by the absorber located in the tube, wherein the reflector portion is configured such that substantially any radiation energy emitted from the absorber onto the reflector portion is either directed to the source or directed back to the absorber. 30. The method of claim 29 , further comprising: converting energy from the light into a thermal energy in the absorber. 31. The method of claim 29 , wherein the source is the sun. 32. The concentrator tube of claim 1 , wherein the aperture member has an optical power of substantially zero. 33. The concentrator tube of claim 1 , wherein the aperture member does not change a direction of the light from the source. 34. The concentrator tube of claim 1 , wherein the reflector portion is configured to compensate for aberrations in the light entering the concentrator tube due to refraction by the aperture member. 35. The concentrator tube of claim 1 , wherein the absorber has a tapered form factor. 36. The concentrator tube of claim 1 , wherein the reflector portion is configured such that a gap exists between the absorber and a bottom section of the reflec