DE1544134C - Process for isotope enrichment using the hot-cold process. Elimination from: 1235272 - Google Patents

Description

If, in the case of deuterium, it is mainly the exit from the hot tower 18, the isotopic exchange reaction following the gas takes place: the current is divided and part of the bottom 37 of the hot Tower 36 fed to the second stage. The other

HDS + H ₂ O = ^ = H ₂ S + HDO the other part is via a cooler and dehumidifier

5 75 after the bottom of the cold tower 14 of the first gasf. liquid gas liquid _{level there it is m} i _{t that of the} head of the

cold tower 28 of the second stage coming

The enrichment effect is based on the fact that gas flow is united. This flows in the cold tower 14 that at low temperature the right side of the sliding hydrogen sulfide gas in countercurrent to the inflow, so the accumulation of deuterium in the io water goes up. This is where the enrichment takes place Water phase is favored. With correct penetration the heavy hydrogen isotopes in the water phase conduct of the proceedings arises in the hot and in place. The gas leaves the head of the cold tower cold zones a concentration gradient, and Deu- 14 and flows through a heat exchanger and terium collects as heavy water on the ground Moisture 78. Here it is in direct contact with the cold zone. 15 upstream of the dotted auxiliary water circuit

In the drawing, the path of the water phase is also warmed and moistened, which in turn is indicated by solid lines, while the circular contact in the heat exchanger 75 and the hydrogen sulfide phase through the analogous heat exchangers 85 of the dashed line below. A dotted fen through the line coming from the hot towers indicates the path of a closed auxiliary hydrogen sulfide gas that was heated.
Water cycle that does not take part in the reaction that leaves the heat exchanger 78. The path of the steam that is heated and humidified, ie introduced for the repeated layer, is indicated by a dash-dotted line. Participating in the cycle conditioned gas flows

The drawing shows the first two stages of a (not shown) via the line 21 again to the multi-stage system for carrying out the process 25 bottom of the hot tower 18 of the first stage. Darens. Each stage consists of one hot and one with, the cycle is closed,
cold tower, the first tier from the cold tower 14 to the right of towers 28 and 36 the second

and the hot tower 18, the second stage from the stage is in the drawing schematically the connection cold tower 28 and the hot tower 36. In the circuit of the gas phase to a (not geTurm 14 shows an upward countercurrent 30) third stage is indicated.

of gas (H ₂ S) present, the temperature in the flow of the from the hot to the cold tower of the

A separator 97 is a separator 97 of this cold exchange reactor with the gas flowing in the first zone at about 20 ° C will hold, for example provided at a pressure of. In this you can carry around 5 at. Water vapor fractions separated by condensation

The emerging at 15 at the bottom of the tower 35 to be. They flow through line 98, given liquid will be shared. A part is via a pump and a Line 25 the cold tower 28 of the following stage preheater, in the hot tower 18 back. A forwarded. The other part is, of course, a corresponding separator via the line 16 provided in the head of the first stage hot tower 18 (not shown) in each subsequent stage directed. Before that, he goes through a heat test.

exchanger 17, in which it is preheated. The head For the inventive deposition of co-

of the hot tower 18, the hydrogen sulfide components carried from the ground are also removed from the water hot tower 36 of the following stage withdrawn phase is in line 22, with which the liquid Water supplied. Phase withdrawn at the bottom of the hot tower 18

In the hot tower 18, a counter 45, a contact separator 67 is again provided. This flow of gas available for the separation that takes place at 80 ° C is done in a simpler, but more effective way the exchange reaction. The one at 20 at the bottom of the way without any significant additional energy on the tower escaping hot liquid is the wall. The ones from the plant to compensate for flow the plant. Before it is discarded, it can be used to warm up and humidify the gas Via a line 24 for heating the heat 50 amount of steam required in the various stages exchanger 17 and analog heat exchanger, such as 32, before it enters the hot tower 18, for the following levels can be used. used for this purpose. The one on the line

In the same way as in the first stage, steam supplied in 66 is countercurrent to the the second stage, the drain liquid withdrawn from the cold tower 28 at 29 of the system into the the exiting liquid phase is divided and a part is filled via 55 contact separators 67. This will make the a line 40 to the cold tower of a (undissolved hydrogen sulfide from the drainage liquid showed) third stage fed. The other part goes away and along with the steam through that Via the line 31 and the preheater 32 to the drain line 68 after the hot tower 18 zurückdem Head of the hot tower 36 of the second stage. brought. A separating effect can be achieved

Before it enters, it is with the current of the hot 60 den, in which less than 1 part per million as the overflow tower of the third stage remains.
Mixed phase. For increasing the temperature in the separator and for

The flow of the gaseous phase is in iden- improvement of its effectiveness is also more pretending, counter-rotating cascade branch out, see the emerging from the separator and with the difference that it is a closed stream of the this cycle acts. The liquid phase in the soil at 20 through the secondary side of a heat med gas entering the hot tower 18 flows in the exchanger 23, which is on its primary side gen flow to the liquid phase upwards. According to the stream entering separator 67

the liquid phase flows through. The temperature in the line is, for example, 80 ° C 22 increased to about 85 ° C. in line 24.

After the absorption of heat from the water flowing into the separator 67, the drainage liquid can be used via line 24 to feed the preheaters 17, 32, etc., as described above, before it is discarded.

The separation device described can be used both in a single-stage system and in the first stage of a multi-stage system can be used with advantage.

1 sheet of drawings

Claims (3)

1 2 similar phase exiting the cold zone of the previous stage before entering the claims: to mix the hot zone of the same stage. It has also been suggested that the second phase should also be branched off in a corresponding, counter-rotating cascade 1. Process for isotope enrichment after lead, whereby the multiple Temperatuiumkehdem Hot-cold process, in which a liquid stanchion in connection with the moisture changes and a gas phase, both of which enrich the gaseous phase in a simple manner Contain isotope, are conducted in countercurrent, adjust manner yourself and therefore with constant characterized in that the io yield and separation performance are an energy saving hot zone leaving liquid phase is achieved in one. Separator in countercurrent to a hotter The invention has a further improvement on Stream of the liquid phase in gaseous form led separation performance of such processes to the goal. For this is, whose non-condensed fractions together, the process according to the invention is thereby mixed with the extracted from the liquid phase indicates that the one leaving the hot zone benen proportions of the gas phase in the hot zone liquid phase in a separator in countercurrent and that entering the separator to a hotter stream of the liquid phase in gas liquid phase through which the impression is passed, its non-condensed parts Separator leaving the liquid phase is preheated together with the one from the liquid phase. ; . . 20 fractions of the gas phase in the hot zone 2. The method according to claim 1, characterized in that the separator indicates that the liquid phase flowing from the cold to the hot liquid phase through the separator zone is preheated by the liquid phase leaving the zone .
Separator leaving stream of liquid. The advantage of this method is that the phase after the heat transfer to the phase from the system, which is present in the separation through which the gas-conveying separator flows from escaping, is largely avoided. with practically no additional energy input 3. The method according to claim 1 or 2, characterized in a very effective manner, wherein by the characterized in that in the case of a multi-stage process, the entering into the separator is preheated the non-confluent phase withdrawn from the separator has the effect that only a small condensed fractions together with those introduced from the part of the gas for separation liquid phase expelled portions of the gas stream of the liquid phase by condensation in the hot zone of the - regarding the loren goes. Task of the liquid phase - first stage because the liquid emerging from the separator be directed. 35 phase, even after it has been used to preheat the in the Separator entering liquid phase has been used, inevitably still a slightly higher Temperature than the liquid phase leaving the hot zone, i.e. a higher temperature, - ^: 4.0 when it prevails in the hot zone, this one can Flow of the liquid phase, before it is finally discarded, advantageous to according to the invention '. Preheating from the cold to the hot zone flowing liquid phase can be used.
45 If the procedure is carried out in several stages The invention relates to a method for isotopes that are not withdrawn from the separator Enrichment according to the hot-cold process, with condensed parts together with the absorbed a liquid and a gaseous phase, the menen parts of the gaseous phase in the hot both contain the isotope to be enriched, in the region of the - with regard to the abandonment of the liquid genstrom are directed. 50 phase - first stage passed. For isotope enrichment, so-called hot A preferred embodiment of the invention Cold process known. Here z. B. according to the current method refers to the Deuterium journal "Angewandte Chemie", 1956, p. 11, Zif enrichment with hydrogen sulfide as the gas phase fer 3, a gaseous phase, z. B. H ₂ S, in the circuit and water as the liquid phase, with a constant through a hot and then through a cold 55 water vapor stream for heating and balancing zone of a column and the isotopes containing the moisture losses of the overall system in the tend liquid phase Countercurrent is initiated through the cold hot zone. In this case, the front and the hot zone are carried out. The product is drawn off from the water vapor stream before its liquid phase between the hot zone and the entry into the hot zone through the separator-cooled zone. . 60, where it removes the sulfuric acid carried by the water To multiply the separating effect, one switches hydrogen components into oneself,
several such columns in a row. So the method according to the invention is on hand e.g. from US Pat. No. 2,787,526, which is explained in more detail in the drawing, which schematically shows a shows the liquid phase after passing through the cold system for carrying out the process. When Zone to divide a part in the hot zone of the 65 example is the enrichment of the heavy wasgledchen Stage and the other part in the cold isotopic deuterium and tritium under VerZone the next stage and the use of water as the liquid phase and welding Zone exiting liquid phase with that selected from hydrogen sulfide as the gaseous phase. It