High concentrating solar device with passive cooling

The invention claimed is: 1. A passively cooled high concentrating photovoltaic, comprising: a photovoltaic receiver including at least one solar cell optionally comprising a heat sink fin; a parabolic dish reflector configured to reflect light toward the at least one solar cell at a distance from the receiver substantially at a focal point of the reflected light; and a plurality of thermally conductive heat pipes that include a sealed structure containing a working fluid and having a direct thermal contact between the photovoltaic receiver and the reflector to transfer heat away from the photovoltaic receiver and that support the photovoltaic receiver, wherein the parabolic dish reflector is made of a thermally conductive material and is configured to absorb heat transferred from the receiver via the heat pipes, wherein the at least one solar cell includes a plurality of multi-junction solar cells, wherein the heat pipes extend parallel to each other, from a top plan view, wherein thermally conductive heat pipes are support rods or bars, each having a first end directly contacting the photovoltaic receiver and a second end directly contacting the parabolic dish reflector, wherein the parabolic dish reflector only contacts the photovoltaic receiver via the ends of heat pipes. 2. The high concentrating photovoltaic of claim 1 , wherein the at least one solar cell includes a plurality of triple junction solar cells. 3. The high concentrating photovoltaic of claim 1 , wherein the heat pipes have a rectangular cross section with longer sides that are arranged parallel to an orthogonal axis through the photovoltaic receiver. 4. The high concentrating photovoltaic of claim 1 , wherein the photovoltaic receiver includes 16 triple junction solar cells attached to an aluminum back plate. 5. The high concentrating photovoltaic of claim 1 , wherein the heat pipes are flat heat pipes. 6. The high concentrating photovoltaic of claim 1 , wherein the at least one solar cell are mounted to an aluminum back plate, wherein the aluminum back plate is connected to the thermally conductive heat pipes. 7. The high concentrating photovoltaic of claim 1 , wherein the parabolic dish reflector tracks the sun using a flexible support tracker. 8. The high concentrating photovoltaic of claim 7 , wherein the flexible support tracker is configured to move a position of the parabolic dish reflector in increments of about 0.2° or smaller. 9. The high concentrating photovoltaic of claim 7 , wherein the flexible support tracker is a dual-axis tracker configured to move the parabolic dish reflector over a range of motion to receive the maximum amount of direct sunlight. 10. The high concentrating photovoltaic of claim 1 , wherein the sealed structure of the flat heat pipes includes micro channels that circulate the working fluid. 11. The high concentrating photovoltaic of claim 1 , wherein the working fluid is distilled water. 12. The high concentrating photovoltaic of claim 1 , wherein the working fluid is an alkali metal. 13. The high concentrating photovoltaic of claim 1 , wherein the sealed structure of the flat heat pipes is made of aluminum. 14. The high concentrating photovoltaic of claim 1 , wherein the sealed structure of the flat heat pipes is made of copper. 15. The high concentrating photovoltaic of claim 1 , comprising no further component as a heat sink besides the heat pipes and the parabolic dish reflector, wherein the parabolic reflective dish is mounted on only one arm. 16. The high concentrating photovoltaic of claim 15 , wherein the receiver is rectangular, having a first, second, third, and fourth side, the first side being parallel to and opposite the third side, the second side being parallel to and opposite the fourth side, the first and third sides being perpendicular to the second and fourth sides, wherein the heat pipes extend parallel to the second and fourth sides and perpendicular to the first and third sides of the receiver.