Foldable parabolic solar collector

The invention claimed is: 1. A foldable parabolic solar collector, comprising: a first panel having a semi-parabolic shape and a first reflective inner surface; a central tube, the first panel being fixed to the central tube; a second panel having a semi-parabolic shape and a second reflective inner surface, the second panel being pivotably mounted to the central tube with the second reflective inner surface of the second panel facing the first reflective inner surface of the first panel; a hollow receiver tube disposed between the first panel and the second panel, the hollow receiver tube being pivotably mounted to the central tube and configured for carrying a heat transfer fluid; a tracking motor coupled to the central tube, the tracking motor configured to rotate the central tube; a torque sensor positioned between the tracking motor and the central tube, the torque sensor configured to measure a torque between the tracking motor and the central tube; a servomotor connected to the central tube and the second panel, the servomotor configured to pivot the second panel about the central tube; a controller having processing circuitry, configured to control the tracking motor to direct an axis of symmetry passing through the central tube and the hollow receiver tube toward a position of the sun, receive torque data from the torque sensor and determine a torque between the tracking motor and the central tube, and control the servomotor to cause the second panel to pivot between an open position, in which the first panel and the second panel form a substantially parabolic shape with the hollow receiver tube disposed along a focal line of the parabolic shape, and a closed position, in which the second panel and the first panel substantially enclose the hollow receiver tube, when it is determined by the controller that the torque between the tracking motor and the central tube exceeds a predetermined torque threshold; a first light sensor disposed on the first reflective inner surface, the first light sensor configured to measure first solar irradiance corresponding to incident solar irradiance on the first reflective inner surface of the foldable parabolic solar collector; and a second light sensor disposed on a back side of the foldable parabolic solar collector, the second light sensor configured to measure second solar irradiance corresponding to incident solar irradiance on the back side of the foldable parabolic solar collector, wherein the controller is further configured to receive first solar irradiance data from the first light sensor, control the servomotor to cause the second panel to pivot from the open position to the closed position when the first solar irradiance data is below a first predetermined solar irradiance threshold, receive second solar irradiance data from the second light sensor, and control the servomotor to cause the second panel to pivot from the closed position to the open position when the second solar irradiance data is above a second predetermined solar irradiance threshold. 2. The foldable parabolic solar collector according to claim 1 , further comprising: a first temperature sensor disposed at a first end of the hollow receiver tube, the first temperature sensor configured to measure a first temperature corresponding to an outlet temperature of the heat transfer fluid, wherein the controller is further configured to receive first temperature data from the first temperature sensor, determine the outlet temperature of the heat transfer fluid from the first temperature data, and control the servomotor to cause the second panel to pivot from the open position to the closed position when the outlet temperature of the heat transfer fluid exceeds a predetermined outlet temperature threshold. 3. The foldable parabolic solar collector according to claim 2 , further comprising: a second temperature sensor disposed at a second end of the hollow receiver tube, the second temperature sensor configured to measure a second temperature corresponding to an inlet temperature of the heat transfer fluid, wherein the controller is further configured to receive second temperature data from the second temperature sensor, determine the inlet temperature of the heat transfer fluid from the second temperature data, and control the servomotor to cause the second panel to pivot from the open position to the closed position when a difference between the outlet temperature and the inlet temperature of the heat transfer fluid is below a predetermined temperature difference. 4. The foldable parabolic solar collector according to claim 1 , further comprising: an electronically-actuatable valve disposed at an end of the central tube; a pressure rail connected to the electronically-actuatable valve to allow liquid to flow from the electronically-actuatable valve to the pressure rail; and a plurality of openings along the pressure rail configured to spray a liquid onto the first reflective inner surface of the first panel and the second reflective inner surface of the second panel, wherein the controller is further configured to actuate the electronically-actuatable valve. 5. The foldable parabolic solar collector according to claim 1 , wherein the hollow receiver tube is enclosed in a glass tube with a space between the hollow receiver tube and the glass tube, the space between the hollow receiver tube and the glass tube is air evacuated and sealed, and the hollow receiver tube is coated with an enamel having an absorptivity of at least ninety percent for solar radiation. 6. The foldable parabolic solar collector according to claim 5 , wherein the enamel absorbs solar radiation having a wavelength between 0.25 microns and 6 microns. 7. The foldable parabolic solar collector according to claim 1 , further comprising: a plurality of first panels fixed to the central tube; and a plurality of second panels pivotably mounted to the central tube. 8. The foldable parabolic solar collector according to claim 7 , wherein the plurality of first panels and the plurality of second panels comprise sheets mounted via a web of structurally-rigid links. 9. The foldable parabolic solar collector according to claim 1 , wherein the torque determined between the tracking motor and the central tube is measured via a current feedback from the tracking motor. 10. A foldable parabolic solar collector, comprising: a first panel having a semi-parabolic shape and a first reflective inner surface; a central tube, the first panel being fixed to the central tube; a second panel having a semi-parabolic shape and a second reflective inner surface, the second panel being pivotably mounted to the central tube with the second reflective inner surface of the second panel facing the first reflective inner surface of the first panel; a hollow receiver tube disposed between the first panel and the second panel, the hollow receiver tube being pivotably mounted to the central tube and configured for carrying a heat transfer fluid; a tracking motor coupled to the central tube, the tracking motor configured to rotate the central tube; a torque sensor positioned between the tracking motor and the central tube, the torque sensor configured to measure a torque between the tracking motor and the central tube; a servomotor connected to the central tube and the second panel, the servomotor configured to pivot the second panel about the central tube; a controller having processing circuitry, configured to control the tracking motor to direct an axis of symmetry passing through the central tube and the hollow receiver tube toward a position of the sun, receive torque data from the torque sensor and det