Solar receiver, method of cooling a solar receiver and a power generation system

The invention claimed is: 1. A solar receiver for capturing solar radiation comprising: a housing, the housing comprising an aperture plate that defines an aperture into an interior of the housing; a radiation capturing element received through the aperture and disposed within the interior of the housing, the radiation capturing element further comprising: a hollow cylinder comprising a cylindrical section and a domed rear end defined by a wall, and an open front end defining a radiation receiving aperture aligned with the aperture in the aperture plate, the hollow cylinder having a length defined by the domed rear end and cylindrical section that is greater than a diameter of the cylindrical section; the wall defining an outwardly extending flange surrounding the radiation receiving aperture; a flow channel defined around the cylindrical section and domed rear end of the radiation capturing element within the housing such that, during operation of the solar receiver, a pressurised working fluid added in the flow channel is passed through the flow channel to absorb thermal energy from the radiation capturing element; the outwardly extending flange of the radiation capturing element secured to an underside of the aperture plate; and a recess defined in the aperture plate around an outer periphery of the outwardly extending flange, the flow channel in communication with the recess such that working fluid that flows through the recess during operation of the solar receiver cools the outer periphery of the outwardly extending flange. 2. The solar receiver according to claim 1 , comprising a porous material within the flow channel that contacts the radiation capturing element and through which the working fluid flows, with the working fluid absorbing at least a portion of the thermal energy via the porous material. 3. The solar receiver according to claim 1 , comprising a reticulated porous ceramic foam within the flow channel that contacts the radiation capturing element and through which the working fluid flows, with the working fluid absorbing at least a portion of the thermal energy via the reticulated porous ceramic foam. 4. The solar receiver according to claim 1 , comprising silicon carbide within the flow channel that contacts the radiation capturing element and through which the working fluid flows, with the working fluid absorbing at least a portion of the thermal energy via the silicon carbide. 5. The solar receiver according to claim 1 , wherein an inlet to the flow channel is arranged to direct the working fluid to the recess in the aperture plate around the outer periphery of the outwardly extending flange. 6. The solar receiver according to claim 1 wherein when in use impingement cooling reduces thermal stresses caused by absorption of solar radiation by a front portion of the radiation capturing element proximate the radiation receiving aperture. 7. The solar receiver according to claim 1 , further comprising a clamp that secures the outwardly extending flange of the radiation capturing element to the aperture plate. 8. The solar receiver according to claim 7 , further comprising a gasket between one or both of: a) the flange and the housing; and b) the flange and the clamp. 9. The solar receiver according to claim 8 , wherein the gasket is comprised of a material selected from the group consisting of graphite, ceramic fibres and nickel-based superalloys. 10. The solar receiver according to claim 7 , wherein the flow path for the working fluid includes chambers formed in the clamp. 11. The solar receiver according to claim 1 , wherein the radiation capturing element is formed of a nonporous material capable of withstanding temperatures in excess of 1000° C. 12. The solar receiver according to claim 1 , wherein the radiation capturing element is formed of silicon carbide. 13. The solar receiver according to claim 1 , wherein the radiation capturing element is formed of sintered silicon carbide or silicon infiltrated silicon carbide. 14. The solar receiver according to claim 1 , wherein the domed end of the radiation capturing element is opposite the radiation receiving aperture. 15. The solar receiver according to claim 1 , wherein the flow channel around the radiation capturing element merges into a working fluid outlet duct of the solar receiver. 16. The solar receiver according to claim 1 , wherein the working fluid is air or helium. 17. A power generation system comprising at least one solar receiver according to claim 1 , further comprising a subsequent power generating plant component, wherein each outlet from the flow channel around the radiation capturing element is coupled to the subsequent power generating plant component. 18. A power generation system comprising at least one solar receiver according to claim 1 , further comprising a gas turbine, wherein each outlet from the flow channel around the radiation capturing element is coupled to the gas turbine. 19. A power generation system comprising at least one solar receiver according to claim 1 , further comprising a combustor, and; a gas turbine, wherein each outlet from the flow channel around the radiation capturing element is coupled to the combustor for heating of the working fluid before it is passed to the gas turbine. 20. A power generation system comprising at least one solar receiver according to claim 1 , further comprising a subsequent power generating plant component, wherein each outlet from the flow channel around the radiation capturing element is coupled to the subsequent power generating plant component and several solar receivers are arranged to feed their working fluid outputs in parallel to the subsequent power generating plant component.