Heat pipe aftercooling system for a turbomachine

1 . A turbomachine comprising: a compressor including an intake portion and an outlet portion, the compressor compressing air received at the intake portion to form a compressed airflow that exits into the outlet portion; a combustor operably connected with the compressor, the combustor receiving the compressed airflow; a turbine operably connected with the combustor, the turbine receiving combustion gas flow from the combustor; an aftercooler operatively connected to the outlet portion of the compressor, the aftercooler including a plurality of heat pipes that extend into the outlet portion, the plurality of heat pipes operatively connected to one or more manifolds, the plurality of heat pipes and the one or more manifolds are configured to transfer heat from the compressed airflow in the outlet portion to a plurality of heat exchangers. 2 . The turbomachine of claim 1 , the plurality of heat pipes further comprising a heat transfer medium including one or combinations of: aluminum, beryllium, beryllium-fluorine alloy, boron, calcium, cobalt, lead-bismuth alloy, liquid metal, lithium-chlorine alloy, lithium-fluorine alloy, manganese, manganese-chlorine alloy, mercury, molten salt, potassium, potassium-chlorine alloy, potassium-fluorine alloy, potassium-nitrogen-oxygen alloy, rhodium, rubidium-chlorine alloy, rubidium-fluorine alloy, sodium, sodium-chlorine alloy, sodium-fluorine alloy, sodium-boron-fluorine alloy, sodium nitrogen-oxygen alloy, strontium, tin, zirconium-fluorine alloy. 3 . The turbomachine of claim 1 , the plurality of heat pipes further comprising a molten salt heat transfer medium including one or combinations of, potassium or sodium. 4 . The turbomachine of claim 1 , the plurality of heat pipes located in a compressor discharge case and radially inward of the combustor. 5 . The turbomachine of claim 1 , the plurality of heat pipes located in the compressor's outlet portion and radially outward from the combustor. 6 . The turbomachine of claim 1 , the plurality of heat pipes located in the compressor's outlet portion and positioned radially inward of the combustor and radially outward from the combustor. 7 . The turbomachine of claim 1 , wherein the one or more manifolds form part of a heat transfer loop, and the heat transfer medium in the heat transfer loop is at least one of: water, steam, glycol or oil. 8 . The turbomachine of claim 1 , wherein the plurality of heat pipes have a cross-sectional shape, the cross sectional shape generally comprising at least one of: circular, oval, or polygonal. 9 . The turbomachine of claim 1 , the plurality of heat pipes further comprising a plurality of fins, the plurality of fins configured to increase the heat transfer capability of the plurality of heat pipes. 10 . The turbomachine of claim 1 , the plurality of heat exchangers including a heat pipe heat exchanger operably connected to the plurality of heat pipes and the one or more manifolds, and the heat pipe heat exchanger also operably connected to: a fuel heating heat exchanger; or a heat recovery steam generator heat exchanger; or a fuel heating heat exchanger and a heat recovery steam generator heat exchanger. 11 . An aftercooler for a turbomachine, the turbomachine including a compressor, a combustor operably connected with the compressor, and a turbine operably connected with the combustor, the aftercooler comprising: a plurality of heat pipes that extend into an outlet portion of the compressor, the plurality of heat pipes operatively connected to one or more manifolds, the plurality of heat pipes and the one or more manifolds are configured to transfer heat from a compressed airflow in the outlet portion to a plurality of heat exchangers. 12 . The aftercooler of claim 11 , the plurality of heat pipes further comprising a heat transfer medium including one or combinations of: aluminum, beryllium, beryllium-fluorine alloy, boron, calcium, cobalt, lead-bismuth alloy, liquid metal, lithium-chlorine alloy, lithium-fluorine alloy, manganese, manganese-chlorine alloy, mercury, molten salt, potassium, potassium-chlorine alloy, potassium-fluorine alloy, potassium-nitrogen-oxygen alloy, rhodium, rubidium-chlorine alloy, rubidium-fluorine alloy, sodium, sodium-chlorine alloy, sodium-fluorine alloy, sodium-boron-fluorine alloy, sodium nitrogen-oxygen alloy, strontium, tin, zirconium-fluorine alloy. 13 . The aftercooler of claim 11 , the plurality of heat pipes further comprising a molten salt heat transfer medium including one or combinations of, potassium or sodium. 14 . The aftercooler of claim 13 , the plurality of heat pipes located in at least one of: the compressor's outlet portion and radially inward of the combustor, and the compressor's outlet portion and radially outward from the combustor. 15 . The aftercooler of claim 14 , the plurality of heat exchangers including a heat pipe heat exchanger operably connected to the plurality of heat pipes and the one or more manifolds, and the heat pipe heat exchanger also operably connected to: a fuel heating heat exchanger; or a heat recovery steam generator heat exchanger; or a fuel heating heat exchanger and a heat recovery steam generator heat exchanger. 16 . The aftercooler of claim 15 , wherein the plurality of heat pipes have a cross-sectional shape, the cross sectional shape generally comprising at least one of: circular, oval, or polygonal; and wherein the plurality of heat pipes further comprise a plurality of fins, the plurality of fins configured to increase the heat transfer capability of the plurality of heat pipes. 17 . A method of extracting heat from a compressed airflow generated by a turbomachine, the method comprising: passing an airflow through a compressor, the compressor acting on the airflow to create a compressed airflow discharged into a compressor discharge case; extracting heat from the compressed airflow by passing the compressed airflow over a plurality of heat pipes; conducting heat from the plurality of heat pipes to a heat pipe heat exchanger, the heat pipe heat exchanger configured to transfer heat to a fuel heating heat exchanger. 18 . The method of claim 17 , wherein the plurality of heat pipes further comprise a molten salt heat transfer medium including one or combinations of, potassium or sodium. 19 . The method of claim 18 , wherein the plurality of heat pipes are located in one or both of: a compressor discharge case radially inward of the combustor, and the compressor discharge case radially outward from the combustor. 20 . The method of claim 19 , the heat pipe heat exchanger operably connected to a circuit including a heat recovery steam generator heat exchanger.