- Nuclear reactor coolant
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Nuclear reactor coolants Coolant Melting point Boiling point Light water at 155 bar 345 °C Mercury -38.83 °C 356.73 °C NaK eutectic -11 °C 785 °C Sodium 97.72 °C 883 °C FLiBe 459 °C 1430 °C Lead 327.46 °C 1749 °C Lead-bismuth eutectic 123.5 °C 1670 °C A Nuclear reactor coolant is a coolant in a nuclear reactor used to remove heat from the nuclear reactor core and transfer it to electrical generators and the environment. Frequently, a chain of two coolant loops are used because the primary coolant loop takes on short-term radioactivity from the reactor.
Almost all currently operating nuclear power plants are light water reactors using ordinary water under high pressure as coolant and neutron moderator. About 1/3 are boiling water reactors where the primary coolant undergoes phase change to steam inside the reactor. About 2/3 are pressurized water reactors at even higher pressure. Current reactors stay under the critical point at around 374 °C and 218 bar where the distinction between liquid and gas disappears, which limits thermal efficiency, but the proposed supercritical water reactor would operate above this point.
Fast reactors have a high power density and do not need neutron moderation. Most have been liquid metal cooled reactors using molten sodium. Lead and other metals have also been proposed and occasionally used.
Molten salts share with metals the advantage of low vapor pressure even at high temperatures, and are less chemically reactive than sodium. Salts containing light elements like FLiBe can also provide moderation. In the Molten-Salt Reactor Experiment it even served as a solvent carrying the nuclear fuel.
Gases have also been used as coolant. Helium is extremely inert both chemically and with respect to nuclear reactions but has a low heat capacity, necessitating rapid circulation. Carbon dioxide has also been used. Gases of course need to be under pressure for sufficient density at high temperature.
Some nuclear reactors use sea water to act as a coolant. The primary reason for this is that sea water has a higher specific capacity than normal fresh water. The result is that more energy will be needed to raise the temperature of the sea water hence increasing the amount of energy transferred from the reactor. This decreases the effects of nuclear fission.
References
- Sodium as a Fast Reactor Coolant, Thomas Fanning, ANL Compares sodium favorably to lead and helium.
Nuclear technology Science Fuel Deuterium · Fertile material · Fissile · Isotope separation · Plutonium · Thorium · Tritium · Uranium (enriched • depleted)Neutron Activation · Capture · Cross-section · Fast · Fusion · Generator · Poison · Radiation · Reflector · Temp · ThermalReactors Boiling (BWR · ABWR) · Heavy (CANDU · PHWR · SGHWR) · Natural (NFR) · Pressurized (PWR · VVER · EPR) · Supercritical (SCWR)Advanced gas-cooled (AGR) · Magnox · Pebble bed (PBMR) · RBMK · UHTREX · Very high temperature (VHTR)FLiBeNone
(Fast)Breeder (FBR) · Integral (IFR) · Liquid-metal-cooled (LMFR) · SSTAR · Traveling Wave (TWR)
Generation IV by coolant: (Gas (GFR) · Lead (LFR) · Sodium (SFR))OtherPower Medicine TherapyWeapon TopicsListsWaste ProductsActinide: (Reprocessed uranium · Reactor-grade plutonium · Minor actinide) · Activation · Fission (LLFP)DisposalDebate Nuclear power debate · Nuclear weapons debate · Anti-nuclear movement · Uranium mining debate · Nuclear power phase-outCategories:- Nuclear reactor coolants
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