Solar power generation system

The invention claimed is: 1. A solar power generation system comprising: a concentrator that collects solar heat; an absorber having a cavity to which solar heat collected by the concentrator is transferred, formed therein; heat pipes that are disposed to surround an outer peripheral surface of the absorber and absorb heat of the absorber; a first heat exchanger having a circulation pipe and a casing that performs heat-exchanging with the heat pipes and absorbs heat of the heat pipes, a front side of the casing having an opening for collecting the solar heat; a thermal conversion electricity generator that generates electricity by receiving heat from the first heat exchanger; and a second heat exchanger that connects the circulation pipe of the first heat exchanger and the thermal conversion electricity generator and performs heat-exchanging between the circulation pipe and the thermal conversion electricity generator, wherein the circulation pipe is directly in physical contact with a surface of a rear side of the casing and passes through the second heat exchanger and the circulation pipe is parallel to the surface of the rear side of the casing. 2. The solar power generation system of claim 1 , wherein the heat pipes are disposed radially on the outer peripheral surface of the absorber, and each heat pipe is disposed to surround the periphery of the absorber. 3. The solar power generation system of claim 1 , wherein the absorber comprises: a cylindrical portion, a front side of which is open and which forms the cavity; a curved surface portion that extends backward from the cylindrical portion; and the heat pipes being arranged radially, and each of the heat pipes comprises a rectilinear pipe portion disposed in a longitudinal direction of the cylindrical portion and a bent pipe portion that extends from the rectilinear pipe portion and is bent to correspond to the curved surface portion. 4. The solar power generation system of claim 2 , wherein a plurality of seating grooves are formed radially in the outer peripheral surface of the absorber so that the plurality of heat pipes are seated in the plurality of seating grooves. 5. The solar power generation system of claim 1 , wherein an auxiliary cooler is installed in the circulation pipe and cools a circulation fluid condensed by the second heat exchanger at a set temperature. 6. The solar power generation system of claim 1 , wherein, the circulation pipe is configured to guide a circulation fluid absorbing heat from the heat pipes toward the thermal conversion electricity generator and circulate the circulation fluid, of which heat is taken away from the thermal conversion electricity generator, toward the heat pipes, the casing is configured to surround the plurality of heat pipes. 7. The solar power generation system of claim 1 , wherein the thermal conversion electricity generator comprises an alkali metal thermal to electric converter (AMTEC). 8. The solar power generation system of claim 1 , wherein the concentrator is of a dish type. 9. A solar power generation system comprising: a concentrator that collects solar heat; an absorber having a cylindrical shape in which one side of the absorber is open so that a cavity to which solar heat collected by the concentrator is transferred, is formed in the absorber; heat pipes being disposed to surround the periphery of the absorber in the longitudinal direction, each of the heat pipes having a bent pipe shape and being radially arranged and absorbing heat of the absorber; a first heat exchanger comprising a circulation pipe in which a circulation fluid that circulates by performing heat-exchanging with the heat pipes and by absorbing heat is filled, and a casing formed to surround the circulation pipe and the heat pipes, a front side of the casing having an opening for collecting the solar heat; and an alkali metal thermal to electric converter (AMTEC) that is disposed so that the circulation pipe passes through the AMTEC and that generates electricity by receiving heat from the circulation pipe; and a second heat exchanger that connects the circulation pipe of the first heat exchanger and the AMTEC and performs heat-exchanging between the circulation pipe and the AMTEC, wherein the circulation pipe is directly in physical contact with a surface of a rear side of the casing and passes through the second heat exchanger and the circulation pipe is parallel to the surface of the rear side of the casing.