Internally heated concentrated solar power (CSP) thermal absorber

We claim: 1. An internally heated energy generating system, comprising: an energy generating device that is a thermoelectric power generator comprising a thermoelectric module located directly between a thermal mass and a cold side heat sink, the cold side heat sink comprising a plurality of fins to dissipate heat; at least one electric heating unit attached to a surface of the thermal mass, and wherein the at least one electric heating unit is configured to preheat the thermoelectric module via the thermal mass to expedite a startup time of the energy generating device to increase efficiency of a production of energy; a housing; and a light-transparent reservoir comprising a material that is transparent to sunlight rays and that forms a portion of a curved exterior side of the housing, wherein the light-transparent reservoir is configured to allow the sunlight rays to enter into the housing to reach and heat the thermal mass by penetrating through the material of the curved exterior side of the housing, the sunlight rays heating the thermal mass to cause the energy generating device to generate electricity, wherein the at least one electric heating unit is configured to heat the thermal mass in no-sunlight conditions to cause the energy generating device to generate electricity in no-sunlight conditions. 2. The internally heated energy generating system of claim 1 , wherein the thermoelectric power module comprises a pair of flat plates and a plurality of semiconductor pillars located in between the flat plates. 3. The internally heated energy generating system of claim 1 , wherein the thermoelectric power generator comprises a hot end and a cold end. 4. The internally heated energy generating system of claim 1 , wherein leads are attached to the thermoelectric module, and the thermoelectric module is configured to output electricity via the leads. 5. The internally heated energy generating system of claim 1 , wherein the thermoelectric power generator operates as a thermal battery. 6. The internally heated energy generating system of claim 1 , wherein the at least one electric heating unit is attached to leads. 7. The internally heated energy generating system of claim 6 , wherein the leads are configured to receive electrical input. 8. The internally heated energy generating system of claim 1 , wherein the at least one electric heating unit comprises at least one resistor element. 9. The internally heated energy generating system of claim 1 , wherein the at least one electric heating unit is attached to leads, and the leads are configured to receive electrical input. 10. An internally heated energy generating system, comprising: an energy generating device that is a thermoelectric power generator comprising a thermoelectric module located directly between a thermal mass and a cold side heat sink; at least one electric heating unit attached to a surface of the thermal mass; a housing; and a light-transparent reservoir comprising a material that is transparent to sunlight rays and that forms a portion of an exterior side of the housing, wherein the light-transparent reservoir is configured to allow the sunlight rays to enter into the housing to reach and heat the thermal mass by penetrating through the material of the exterior side of the housing, the sunlight rays heating the thermal mass to cause the energy generating device to generate electricity, wherein the at least one electric heating unit is configured to heat the thermal mass in no-sunlight conditions to cause the energy generating device to generate electricity in no-sunlight conditions; wherein the at least one electric heating unit comprises a heating device configured to generate heat to heat the energy generating device. 11. The internally heated energy generating system of claim 10 , wherein the heating device is attached onto a hot end of the thermoelectric power generator. 12. The internally heated energy generating system of claim 10 , wherein the heating device is wrapped around a hot end of the thermoelectric power generator. 13. The internally heated energy generating system of claim 10 , wherein the heating device is plated onto a hot end of the thermoelectric power generator. 14. The internally heated energy generating system of claim 10 , wherein the heating device is integrated into a hot end of the thermoelectric power generator. 15. A method for providing an internally heated energy generating system, the method comprising: providing an energy generating device that is a thermoelectric power generator comprising a thermoelectric module, at least one electric heating unit, a thermal mass, a housing, and a cold side heat sink, wherein the thermoelectric module is located directly between the cold side heat sink and the thermal mass, and wherein the at least one heating unit is attached to a surface of the thermal mass; entering, by sunlight rays, into the housing to reach and heat the thermal mass by penetrating through a material of a curved exterior side of the housing, the sunlight rays heating the thermal mass to cause the energy generating device to generate electricity, wherein a light-transparent reservoir comprises the material, which is transparent to the sunlight rays, and wherein the light-transparent reservoir forms a portion of the curved exterior side of the housing; preheating, by the at least one electric heating unit, the thermoelectric module via the thermal mass to expedite a startup time of the energy generating device to increase efficiency of a production of energy; heating, by the at least one electric heating unit, the thermal mass in no-sunlight conditions to cause the energy generating device to generate electricity in no-sunlight conditions; and dissipating, by a plurality of fins of the cold side heat sink, heat. 16. The method for providing an internally heated energy generating system of claim 15 , wherein the at least one electric heating unit comprises at least one resistor element. 17. The method for providing an internally heated energy generating system of claim 15 , wherein the at least one electric heating unit is attached to leads. 18. The method for providing an internally heated energy generating system of claim 17 , wherein the leads are configured to receive electrical input. 19. The method for providing an internally heated energy generating system of claim 15 , wherein the thermoelectric module comprises a pair of flat plates and a plurality of semiconductor pillars located in between the flat plates. 20. The method for providing an internally heated energy generating system of claim 15 , wherein the thermoelectric power generator comprises a hot end and a cold end. 21. The method for providing an internally heated energy generating system of claim 15 , further comprising outputting, by the thermoelectric module, electricity via leads, which are attached to the thermoelectric module. 22. The method for providing an internally heated energy generating system of claim 15 , wherein the at least one heating unit comprises a heating device attached onto a hot end of the thermoelectric power generator, wrapped around the hot end of the thermoelectric power generator, plated onto the hot end of the thermoelectric power generator, or integrated into the hot end of the thermoelectric power generator.