Solar system for energy production

The invention claimed is: 1. An energy generation system, comprising: a solar energy collection arrangement configured and operable for collecting and reflecting concentrated sunlight radiation; a solar energy receiver configured for receiving the concentrated sunlight radiation from said solar energy collection arrangement and converting said concentrated sunlight radiation to thermal energy in a first working fluid, wherein said solar receiver includes a chimney configured for channeling heat flow generated by natural convection heat losses from said solar receiver; a thermal energy storage unit comprising at least one thermal energy storage module being configured and operable for storing thermal energy; a charging piping arrangement connecting between said solar receiver to said thermal energy storage unit and being configured and operable for carrying a first working fluid transferring heat from said solar receiver to said at least one thermal energy storage module, to thereby enable charging said at least one thermal energy storage module with thermal energy, and carrying said first working fluid back to said solar receiver, after said first working fluid exits said thermal energy storage unit; a power conversion unit configured and operable for accommodating a second working fluid and converting heat delivered by said second working fluid to electricity; a heat discharging piping arrangement connecting between said thermal energy storage unit to said power conversion unit and being configured and operable for carrying said second working fluid for transferring heat from said at least one thermal energy storage module to said power conversion unit, and carrying said second working fluid back to said at least one thermal energy storage module, after said second working fluid exits said power conversion unit; and a cooling module configured for utilizing said heat flow to produce chilled water. 2. The system of claim 1 , wherein said thermal energy storage unit comprises a plurality of thermal energy storage modules connected to one another via an arrangement of pipes accommodating at least one of said first and said second working fluid. 3. The system of claim 1 , wherein at least one of the thermal energy storage modules contains both sensible heat and phase-change materials (PCM), for increasing storage capacity. 4. The system of claim 1 , wherein said solar receiver is mounted on said thermal energy storage unit. 5. The system of claim 1 , wherein said solar receiver comprises at least one thermoelectric array being configured and operable to absorb said heat flow and use said heat flow to produce electricity. 6. The system of claim 1 , wherein said chilled water is used for cooling said second working fluid of said power conversion unit before it is compressed. 7. The system of claim 1 , wherein at least a part of said arrangement of pipes of said at least one of said thermal energy storage modules has at least one of a slanted pipe section and a U shape, to thereby reduce piping length. 8. The system of claim 1 , further comprising at least one of one or more heat exchangers and one or more additional thermal energy storage modules being in fluid communication with said thermal energy storage unit and said power conversion unit, and being configured for receiving heat from said thermal energy storage unit and for supplying heat to said power conversion unit. 9. The system of claim 8 , further comprising an intermediate arrangement of pipes connecting between at least two of the following components: said thermal energy storage unit, said one or more heat exchangers and said additional thermal energy storage modules. 10. An energy generation system, comprising: a solar energy collection arrangement configured and operable for collecting and reflecting concentrated sunlight radiation; a solar energy receiver configured for receiving the concentrated sunlight radiation from said solar energy collection arrangement and converting said concentrated sunlight radiation to thermal energy in a first working fluid; a thermal energy storage unit comprising at least one thermal energy storage module being configured and operable for storing thermal energy; a charging piping arrangement connecting between said solar receiver to said thermal energy storage unit and being configured and operable for carrying a first working fluid transferring heat from said solar receiver to said at least one thermal energy storage module, to thereby enable charging said at least one thermal energy storage module with thermal energy, and carrying said first working fluid back to said solar receiver, after said first working fluid exits said thermal energy storage unit; a power conversion unit configured and operable for accommodating a second working fluid and converting heat delivered by said second working fluid to electricity; a heat discharging piping arrangement connecting between said thermal energy storage unit to said power conversion unit and being configured and operable for carrying said second working fluid for transferring heat from said at least one thermal energy storage module to said power conversion unit, and carrying said second working fluid back to said at least one thermal energy storage module, after said second working fluid exits said power conversion unit; at least one of one or more heat exchangers and one or more additional thermal energy storage modules being in fluid communication with said thermal energy storage unit and said power conversion unit, and being configured for receiving heat from said thermal energy storage unit and for supplying heat to said power conversion unit; and an intermediate arrangement of pipes connecting between at least two of the following components: said thermal energy storage unit, said one or more heat exchangers and said additional thermal energy storage modules; wherein said intermediate arrangement of pipes is configured for accommodating at least one intermediate working fluid being at an intermediate pressure between the pressure of the thermal energy storage unit and that of the power conversion unit. 11. The system of claim 1 , wherein at least a portion of said charging piping arrangement configured for carrying said first working fluid back to said solar receiver, after said first working fluid exits said thermal energy storage unit, is located inside at least one of said thermal energy storage modules. 12. The system of claim 1 , wherein said thermal energy storage unit comprises at least one thermal insulation portion; at least a portion of said charging piping arrangement or of said heat discharging piping arrangement being accommodated within said thermal insulation portion. 13. The system of claim 1 , further comprising a fuel combustor located upstream or downstream of said thermal energy storage unit and being configured for heating said first working fluid or said second working fluid, respectively. 14. The system of claim 1 , wherein said power conversion unit comprises a multi-stages turbine and said discharging piping arrangement is configured such that said second working fluid bypasses a first turbine stage and is introduced into a second turbine stage. 15. The system of claim 1 , wherein at least one pipe of said charging piping arrangement transferring heat from said solar receiver to said thermal energy storage module is placed inside another pipe of said charging piping arrangement, carrying said first working fluid back from said thermal energy storage unit to said solar receiver, forming an annulus configuration. 16. The system