DE4210831C1 - Removing tritium from cool trap of liq. metal cooled reactor - resulting in final mixing and storage of tritium water with cement forming concete - Google Patents

Abstract

Process is for removal of unwanted tritium from the cool trap (1) of a liq. metal cooled nuclear reactor. The cool trap (1) is heated directly by a heater (2), and by inert gas that has already been heated passing through it, to a temp. above that at which hydrides dissociate. The hydrogen (including tritium), so produced, is collected by an inert gas cycle (6) and fed to the prim. side of a permeator (4). In the permeator (7), hydrogen ions diffuse across into the sec. cycle (15) which comprises a circulating acidic gas. Hydrogen and acid react in a discharge chamber (17) to produce water. This water including the tritium ions in then used to produce concrete, in which form the tritium is then stored. USE/ADVANTAGE - The liq. metal circulating in a reactor contains traces of hydrogen and acid, these react with the metal to produce hydrides. The unwanted components are removed by chilling of the cool trap (1). Over a period of time radioactive tritium builds up and impairs operation of the cool trap. Periodically the tritium. Advantageously, by use of the permeator, only hydrogen ions (including tritium) are removed from the circulating inert gas. Therefore no unwanted radioactive elements of much longer half life are removed.

Description

The present invention relates to a method for Cleaning the cold traps of liquid metal cooled reactors of tritium and a device for performing this Procedure.

In cooled with liquid metal, preferably sodium Nuclear power plants will run the coolant regularly Cold traps led in which the temperature of the same is lowered so that contaminants are precipitated, which as a result of the reaction of the liquid metal with traces of oxygen and inevitably present Hydrogen are formed. In particular the hydrides of the Metals form a larger part of those deposited here Fabrics. The hydrides are not only becoming more normal Hydrogen but also its isotopes, especially the radioactive tritium; This leads to after long-term operation of the cold traps in these significant tritium inventory is tied up because of the radiation emitted by him dealing with the Cold traps are difficult, especially if that is in question upcoming nuclear power plant decommissioned and to be canceled.  

From DE 39 30 420 C1 and DE 40 29 222 C1 are procedure and devices for eliminating tritium from radio active waste. This will contaminate mate rialien heated, whereby gases, especially tritium, out be driven. These gases become a reac with oxygen tion brought, u. a. Tritium water is created. This Tritium water is finally knocked down and on disposed of any of the known ways.

DE 36 06 316 C2 relates to the decontamination of the waste gas ses the fuel circuit of a fusion reactor from Ab gas components, especially tritium. For this, the Exhaust gas over an oxidation catalyst with oxygen oxidized and the tritium water obtained from the Ab gas separated.

DE 33 32 346 A1 relates to hydrogen permeation wall, which in particular for filtering out tritium Reactor gas, especially cooling gas from a gas-cooled reak tors, is suitable.  

The object of the present invention is a modification this process to the cold traps of liquid metal to clean cooled nuclear power plants from tritium. It should be borne in mind that in the cold traps too other radionuclides that are deposited at a unchanged application of the known method together would be driven out with the tritium and then formed tritium water with some longer life Would contaminate radiators. That by means of modified process obtained tritium water in addition to be brought into a form with less problems of a final storage than is they are to be expected with a liquid.

A cleaning method is used to solve this problem a cold trap of a liquid metal cooled nuclear energy plant of tritium indicated, the tritium by Er heat expelled from the cold trap and to tritium water is oxidized, whereby

• a) the cold trap on the decomposition temperature of in the hydrides it contains are heated and discharged the expelled tritium with an inert gas is rinsed;
• b) the inert gas loaded with the tritium on the primary side a permeator is fed, with a secondary side of the permeator with an oxygen-containing gas is acted upon;
• c) the tritium diffused on the secondary side with the oxidized gas containing oxygen to tritium water and as such is put down.

Since the silver-palladium tubes are a commercially available Permeators for isotopes of hydrogen, but not are permeable to other nuclides, so it becomes reliable prevents other than the tritium from entering the  Cold trap contained radionuclides on the secondary side reach. The water obtained by the process, the a certain proportion of heavy tritiated Contains water, is in a further embodiment Invention used for the production of concrete bodies are ready for final storage. This represents an easy one without any method that is difficult to perform, to bind water in such a way that it is safe Enclosing none that may be at risk of leakage Wrapping needs more.

In a further embodiment of the invention, the cold trap heated by means of the inert gas passed through. This can in addition to direct heating of the cold trap respectively.

A device for performing the above The method described according to the invention consists of a connectable to the cold trap with its primary side Permeator, a source of inert gas, pumps for circulation of the inert gas and one the permeator on the Secondary side of oxygen-containing gas also a device for heating the cold trap or of the inert gas, and a first container in which a Induced reaction between hydrogen and oxygen can be and a second, connectable to the first and partially water-filled and with a Drain device provided container.

In a further embodiment of the invention is the second Container with its drainage device with a concrete mixing and molding system connectable so that the formed Tritium water can be bound here directly.  

In a further embodiment of the invention Device with a heater for that on the Gas mixture circulating secondary side of the permeator provided to support the permeation effect. The It becomes a specialist at suitable points in the cycle recuperative heat exchangers provide part of the heat applied by the heater to win back when they are withdrawn from the process must become; for example when dar first in Water present in vapor form through condensation to be put down.

In a further embodiment of the invention, the above are listed parts together with any existing Auxiliary systems Parts of a cold trap to be cleaned connectable, transportable unit. This unity then only needs to be connected if necessary, and can be used as a specialized device in cleaning numerous spatially separated cold traps use Find.

An embodiment of the invention is shown in the drawing. In a cold trap 1 for the liquid metal used as a coolant in a nuclear power plant, in particular sodium, which is provided with a heater 2 , a cleaning unit consisting of the parts described below can be connected via couplings 3 . This first comprises a permeator 4 , which is provided with a second heater 5 and on its primary side is part of a gas circuit 6 which closes via the cold trap. After the cold trap 1 has been connected via the couplings 3 , this is first evacuated via a first pump 7 , which can be shut off by a valve, and then from an also lockable storage 8 with an inert gas, for. B. argon, suitably filled up to a pressure of 700 mbar. The filling pressure is checked by means of a pressure gauge 9 . The inert gas is circulated in the circuit 6 by means of a second pump 10 and, if necessary, heated by means of a third heater 11 . In order to separate coolant droplets entrained by the gas flow from the cold trap 1 , a filter 12 is provided. The inert gas emerging from the filter 12 , which has taken up, among other things, hydrogen isotopes in the cold trap 1 , which have been released by the heat-related decomposition of the hydrides contained therein, is reheated with a fourth heater 13 and brought to the operating temperature of the permeator 4 . Another pressure measuring device 14 is used to control the pressure conditions at the permeator 4 . In the permeator 4 , only the hydrogen isotopes, including the tritium, diffuse from the primary circuit 6 into a secondary circuit 15 , which contains an oxygen-containing gas, preferably air, and is maintained by means of a third pump 16 . The gas mixture leaving the permeator 4 and containing oxygen and the hydrogen isotopes is passed into a first container 17 , in which a reaction between these two components can be brought about by means of a discharge path 18 . The water, which is initially in vapor form and is formed here, is passed into a second, partially water-filled container 19 , where it is separated off. Any residual moisture still entrained in the gas stream is separated in a molecular sieve dryer 20 , which is provided with a fifth heater 21 for its occasional regeneration. The regeneration is initiated when the loading limit of the molecular sieve dryer 20 is indicated by the color change of a blue gel cartridge 22 . The oxygen consumed by the reaction in the first container 17 is replaced by a second, also lockable, reservoir 23 , the pressure in the secondary circuit 15 being controlled by means of a third pressure gauge 24 . A sixth heater 25 is arranged before the secondary circuit 15 enters the permeator 4 . Recuperative heat exchangers 26 to 28 are arranged at suitable points both in the primary circuit 6 and in the secondary circuit 15 . The fill level in the second container 19 is checked by means of a fill level meter 29 and the entire process is stopped when the maximum permissible fill is exceeded, or water is discharged via a lockable drain line 30 into a concrete mixing and shaping unit 31 , where the water is set by mixing with cement. The concrete mixing and molding plant 31 is detachably connected to the cleaning unit via further couplings 32 .

Claims (7)

1. A method for cleaning a cold trap ( 1 ) of a liquid metal-cooled nuclear power plant of tritium, the tritium being expelled by heating from the cold trap ( 1 ) and oxidized to tritium water, characterized in that

• a) the cold trap ( 1 ) is heated above the decomposition temperature of the hydrides contained therein and is flushed with an inert gas to discharge the expelled tritium;
• b) the inert gas loaded with the tritium is fed to the primary side ( 6 ) of a permeator ( 4 ), a secondary side ( 15 ) of the permeator ( 4 ) being charged with an oxygen-containing gas;
• c) the tritium diffused onto the secondary side ( 15 ) is oxidized to tritium water with the oxygen-containing gas and is precipitated as such.

2. The method according to claim 1, characterized characterized in that the water for Manufacture of concrete bodies is used that are ready for final storage. 3. The method according to claim 1 or 2, characterized in that the cold trap ( 1 ) is heated by means of the passed through inert gas. 4. Device for performing the method according to one of claims 1 to 3, consisting of

• a) with its primary side ( 6 ) connectable to the cold trap ( 1 ) permeator ( 4 ),
• b) a source ( 8 ) of inert gas,
• c) pumps ( 10 , 16 ) for circulating the inert gas and an oxygen-containing gas acting on the permeator ( 4 ) on the secondary side ( 15 ),
• d) a device ( 2 , 11 ) for heating the cold trap or the inert gas,
• e) a first container ( 17 ) in which a reaction between hydrogen and oxygen can be brought about and
• f) a second, with the first connectable and partially water-filled and provided with a drain device ( 30 ) container ( 19 ).

5. The device according to claim 4, characterized in that the second container ( 19 ) with its drain device ( 30 ) with a concrete mixing and molding system ( 31 ) can be connected. 6. The device according to claim 4 or 5, characterized by a heating device ( 25 ) for the gas mixture circulating on the secondary side of the permeator ( 4 ). 7. The device according to claim 4, 5 or 6, characterized in that the permeator ( 4 ), the second pump ( 10 ), the first and second container ( 17 , 19 ) together with any auxiliary systems ( 7 , 9 , 12 , 20 to 29 ) are parts of a transportable unit that can be connected to the cold trap ( 1 ).