Isolation condenser systems for nuclear reactor commercial electricity generation

What is claimed is: 1. An isolation condenser system for use in a nuclear reactor facility for commercially generating electricity, the system comprising: an inlet configured to provide reactor coolant from a nuclear reactor pressure vessel; an outlet configured to provide the reactor coolant to the nuclear reactor pressure vessel; at least one isolation condenser connected between the inlet and the outlet and immersed in a chamber filled with isolation condenser coolant, wherein the isolation condenser includes a heat exchanger configured to transfer energy from the reactor coolant to the isolation condenser coolant; a reservoir storing additional isolation condenser coolant for the chamber; a check valve allowing coolant flow from the reservoir to the chamber and preventing coolant flow from the chamber to the reservoir; and a switch configured to determine relative coolant level between the chamber and the reservoir and operate the check valve based on the relative coolant level. 2. The system of claim 1 , wherein the switch is passive and includes a first float in the chamber and a second float in the reservoir, and wherein the switch is configured to close the check valve so as to isolate the chamber when the relative position of the first float is below the second float. 3. The system of claim 1 , wherein the reservoir is a pool adjacent to the chamber and connected to the chamber so the isolation condenser coolant flows from the pool to the chamber. 4. The system of claim 1 , wherein the reservoir is larger than the chamber. 5. The system of claim 1 , wherein the entire system is underground. 6. An isolation condenser system for use in a nuclear reactor facility for commercially generating electricity, the system comprising: an inlet configured to provide reactor coolant from a nuclear reactor pressure vessel; an outlet configured to provide the reactor coolant to the nuclear reactor pressure vessel; at least one isolation condenser connected between the inlet and the outlet and immersed in a chamber filled with isolation condenser coolant, wherein the isolation condenser includes a heat exchanger configured to transfer energy from the reactor coolant to the isolation condenser coolant; a reservoir storing additional isolation condenser coolant selectively connected to the chamber so that the isolation condenser coolant can flow in only one direction from the reservoir to the chamber; a plurality of fluidic controls configured to activate the isolation condenser; and a plurality of the isolation condensers, and wherein each fluidic control is configured to activate one of the isolation condensers at a reactor pressure setpoint, wherein the reactor pressure setpoint is different for each one of the fluidic controls such that each one of the isolation condensers is activated at a different reactor pressure. 7. The system of claim 6 , wherein the reservoir is a pool adjacent to the chamber and connected to the chamber so the isolation condenser coolant flows from the pool to the chamber. 8. The system of claim 6 , wherein the reservoir is larger than the chamber. 9. The system of claim 6 , wherein the entire system is underground.