Gas equalization and management system for a molten salt nuclear reactor

What is claimed is: 1 . A molten salt reactor system comprising a reactor vessel; a drain tank; a fuel salt system configured to circulate a molten salt through the reactor vessel; an inert gas system fluidically coupled with the fuel salt system and the drain tank; and wherein the inert gas system is configured to maintain a pressurized volume in a head space of the drain tank by circulating an inert gas along an inert gas flow path; wherein the pressurized volume prevents the molten salt from flowing from the reactor vessel into the drain tank; and wherein the inert gas system is configured to cease maintenance of the pressurized volume in response to a shutdown event; an equalization system configured to equalize pressure of a head space of the reactor vessel and the head space of the drain tank in response to the shutdown event thereby allowing the molten salt to gravitationally drain from the reactor vessel to the drain tank. 2 . The system of claim 1 , wherein the equalization system comprises a flow path with one or more fail-open equilibrium control valves in series with one another and each fluidically coupling the head space of the reactor vessel and the head space of the drain tank. 3 . The system of claim 2 , wherein the flow path comprises a first flow path; and wherein the equalization system further comprises a second flow path with one or more fail-open equilibrium control valves in series with one another and each fluidically coupling the head space of the reactor vessel and the head space of the drain tank. 4 . The system of claim 3 , wherein the equalization system further comprises a cross-connection fluidically coupling the first flow path of the equalization system and the second flow path of the equalization system. 5 . The system of claim 4 , wherein the equalization system further comprises a third flow path with one or more fail-open equilibrium control valves in series with one another and each fluidically coupling the head space of the reactor vessel and the head space of the drain tank. 6 . The system of claim 5 , wherein at least one fail-open equilibrium control valve of the equalization system is associated with a bypass comprising a burst disc. 7 . The system of claim 6 , wherein, in response to the associated fail-open equilibrium valve malfunctioning during the shutdown event, a pressurized gas container is configured to release pressurized contents of the container and cause a rupture of the burst disc, thereby permitting a flow to bypass the associated fail-open equilibrium valve. 8 . The system of claim 6 , wherein in response to the associated fail-open equilibrium valve malfunctioning during the shutdown event, the burst disc may be mechanically or thermally ruptured, thereby permitting a flow to bypass the associated fail-open equilibrium valve. 9 . The system of claim 2 , wherein the inert gas system comprises a pair of fail-open inert gas control valves, and the pair of fail-open inert gas control valves are configured to equalize pressure between the head space of the reactor vessel and the head space of the drain tank in response to the shutdown event. 10 . The system of claim 9 , wherein the pair of fail-open inert gas control valves are configured to equalize pressure between the head space of the reactor vessel and the head space of the drain tank automatically in response to an occurrence of both the shutdown event and a failure of the equalization system to equalize pressure between the head space of the reactor vessel and the drain tank. 11 . The system of claim 1 , wherein the inert gas system comprises a first inert gas vessel, a second inert gas vessel fluidically coupled with the first inert gas vessel, and a compressor in-line between the first inert gas vessel and the second inert gas vessel, the first inert gas vessel is arranged to receive inert gas from at least the inert gas flow path, the compressor is configured to receive a flow of inert gas from the first inert gas vessel, increase a pressure of the flow of inert gas, and cause the flow of inert gas to be delivered to the second inert gas vessel, and the second inert gas vessel is arranged to deliver inert gas to at least the inert gas flow path. 12 . The system of claim 11 , wherein the inert gas system is configured to maintain a first inert gas pressure in the first inert gas vessel at around +2 psig to-2 psig, a second inert gas pressure in the second inert gas vessel at around 50 psig, and a third inert gas pressure in the pressurized volume in the head space of the drain tank at around 30 psig. 13 . The system of claim 1 , further comprising a molten salt loop, wherein the molten salt loop includes a reactor pump, wherein the inert gas flow path comprises a first inert gas flow path; and wherein the inert gas system is further configured to maintain a gas seal at the reactor pump by circulating the inert gas along a second inert gas flow path, the reactor pump configured to drive the molten salt along the molten salt loop, and relieve the gas seal in response to the shutdown event. 14 . A molten salt nuclear reactor system comprising a reactor vessel; a drain tank; a fuel salt system configured to circulate a molten salt through the reactor vessel; an inert gas flow system fluidically coupled with the fuel salt system and the drain tank, and configured to maintain a pressurized volume located in a head space in the drain tank, wherein the pressurized volume prevents molten salt to flow from the reactor vessel into the drain tank, and wherein the inert gas flow system is configured to cease maintenance of the pressurized volume in response to a reactor shutdown event; an equalization system configured to equalize pressure inside a head space in the reactor vessel and the head space in the drain tank in response to the reactor shutdown event, the equalization system comprising a cross-connection fluidically coupling a first flow path of the equalization system and a second flow path of the equalization system; wherein the equalization allows molten salt to flow by gravity from the reactor vessel into the drain tank. 15 . A molten salt nuclear reactor system comprising a reactor vessel; a drain tank; a fuel salt system configured to circulate a molten salt through the reactor vessel; an inert gas flow system fluidically coupled with the fuel salt system and fluidically coupled with the drain tank by an inert gas flow path, and configured to maintain a pressurized volume located in a head space in the drain tank, wherein the pressurized volume prevents molten salt to flow from the reactor vessel into the drain tank, the inert gas flow system comprising a first inert gas vessel, a second inert gas vessel fluidically coupled with the first inert gas vessel, and a compressor in-line between the first inert gas vessel and the second inert gas vessel, wherein the first inert gas vessel is arranged to receive inert gas from at least the inert gas flow path, wherein the compressor is configured to receive a flow of inert gas from the first inert gas vessel, increase a pressure of the flow of inert gas, and cause the flow of inert gas to be delivered to the second inert gas vessel, and wherein the second inert gas vessel is arranged to deliver inert gas to at least the inert gas flow path; wherein the inert gas flow system is configured to cease maintenance of the pressurized volume in response to a reactor shutdown event; an equalization system configured to equalize pressure inside a head space in