DE1198328B - Process for separating gaseous or vaporous substances with average molecular weights over 200, especially isotopes - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY

GERMAN

PATENT OFFICE

EDITORIAL

Int. α .:

BOId

German class: 12 e- 6

Number: 1198 328

File number: K 49161IV c / 12 e

Filing date: March 9, 1963

Opening day: August 12, 1965

Process for separating gaseous or vaporous substances with medium Molecular weights over 200, especially isotopes

Applicant:

Society for nuclear research with limited liability, Karlsruhe, Weberstr. 5

Named as inventor:

Dr. Erwin Becker, Karlsruhe

For separating gaseous or vaporous substances, especially isotopes, with different Molecular weight and / or different gas kinetic cross-sections can be used for the mixture from a nozzle-like opening onto a peeling diaphragm, which is divided into a shell part and one through the diaphragm opening passing through core part disassembled, let flow. The heavy component accumulates in the process in the core part.

This method, which is particularly useful for isotope separation, is relatively expensive tied together. A large number of supplementary measures have therefore already been proposed in order to obtain more favorable conditions.

A well-known suggestion is that Sept.
beam generated from the mixture to be broken down
after exiting the nozzle on the way to
Mechanically deflect the peel-off diaphragm. The one in the
Studies published in the literature show 2

but that the profitability of the separation 20

The process does not improve what is apparently based on the published results the mechanical deflection associated interference but also with the use of a slight additional effect is based. gases technically uninteresting, apparently with the

According to the German patent specification 1096 875, a slight additional gas 25 ben-like eddies in the production of rotating, steep mixture to be separated can lead to unavoidable losses due to friction or turbulence, which is significantly related to the mixture,
lower molecular or atomic weight added With none of the various measures described. However, by taking measures in the area of high masses, improvements in the separation process in the high mass range were particularly important for practical application, for example for gaseous or vaporous substances, in particular iso at average molecular weights over 200 tope , can be achieved in which mixtures of nozzles - as corresponding investigations show like openings from peeling diaphragms that have it in a jacket - no clear advantages are achieved. parts and passing through the aperture

Attempts have therefore already been made to mechanically divert internals to the nozzles used for the core parts, flow towards them and in this way jet generation. It has now been brought up that change the nozzle opening in such a way that these difficulties are avoided, that at least two converging gas flows, if according to the invention the mixture, form a lighter gas stream. This is also added under the additional gas used and the converting jet which can be discharged from the nozzle of light additional gases is reversed on the way to the peeling diaphragm, but is also deflected in the range of more than 40 less than 360 °.
Masses no economic benefits. Further details are given on the basis of the drawing

Another well-known attempt was made to explain this in more detail.

decomposing mixture from the outside tangentially or under FIG. 1 shows a schematic section

small angle in stationary cylindrical, conical device for carrying out the process, Mige or similar chambers of the form Guldin- 45 This consists of a discharge line 19 for the shear body to flow in, it thereby to the jacket part of the gas, one end of which forces the nozzle, about the axis of the rotating screw plate 12 for the nozzle channel 13, while the to form like vortices and which, in relation to the other, free end at the same time serves as a peeling plate 14, Components arranging their density as required For the mechanical deflection there is a baffle to be derived separately. In a special embodiment 50 11 is provided, one end face of which with the In the form of this method, the nozzle plate 12 to be separated forms the nozzle channel 13. This one a light gas was added to the mixture. After the nozzle channel, the mixture is via line 16

(ζ. B. gas to be separated and lighter additional gas) supplied. The second end face of the baffle plate 11 forms, with the peeling plate 14, the peeling channel 15, from which the core part of the gas enriched in the heavier component is drawn off via the line 17. The baffle 11, for. B. in the form of a half-cylinder jacket, at the same time delimits the space 18 in which the jacket portion of the gas that is removed through the discharge line 19 occurs. In the example shown in FIG. 1, the nozzle plate is designed in such a way that a Laval nozzle results. However, good results can also be achieved with convergent nozzles. In the example chosen, the deflection plate is designed in such a way that an average deflection of the beam of almost 180 ° results. However, good results can also be obtained with a smaller deflection angle, e.g. B. 90 °, or a larger, z. B. 250 °, can be achieved. Since an increase in the deflection angle beyond 360 ° requires the generation of harmful helical vortices, a deflection angle below 360 ° must be observed in any case.

In the device shown, the peeling channel 15 has an approximately rectangular longitudinal cross-section. However, the backflow effect can be influenced by the cross section in the direction of flow narrowed or expanded.

In Fig. 2 shows a further embodiment of the device in section. Here are a common convergent nozzle 21 with feed line 210, two deflection plates 22 and 23 opposite. The core part of the gas is withdrawn via lines 24 and 25, the jacket part via lines 26 and 27. The entire arrangement can again be expanded as desired in the direction perpendicular to the plane of the drawing. In the case of the in FIG. 2, however, a rotationally symmetrical embodiment is also possible, as is obtained by rotating the section shown in FIG. 2 about the axis 28-29 . In this case, lines 24 and 25 on the one hand and lines 26 and 27 on the other hand are combined to form a ring line.

Tests have shown that particularly favorable results can be achieved if the width of the nozzle at the narrowest point less than 1 mm and if the radius of curvature is that for deflecting the jet used area in the area essential for beam deflection is less than 5 mm. Included does not need the radius of curvature in the entire area essential for the beam deflection to be constant. The most favorable form for each mixture can be found relatively easily by trial and error be determined.

In the method according to the invention with mechanical beam deflection, relatively high additives result on light gas under optimal conditions. This is particularly the case with the basic mixtures to be separated with large average molecular weights, an addition of light gas of 1000 mol percent and more has proven successful.

The ratios of the pressures in lines 16, 19 and 17 or 210, 24, 25 and 26 and 27 can be varied within relatively wide limits. However, it has been shown that optimal separation effects can be achieved even with relatively low pressure ratios. In many cases, particularly favorable conditions can be achieved if the ratio of the pressures in the nozzle supply line 16 and the discharge line 19 is kept below 10 and the ratio of the pressures in the nozzle supply line 16 and the discharge line 17 is kept below 5. The most appropriate absolute pressure in the nozzle feed line depends on the type of gas mixture used and can easily be determined by trial and error. Pressures in the nozzle feed line between 1 and 0.05 atm absolute have proven to be particularly favorable.

Of course, it is also easily possible to have several separating devices one behind the other or to connect in parallel. With a series connection one should as in the German patent specification 1 096 875 expediently the various gas supply and discharge lines with one another combine so that only streams of the same composition of the basic mixture to be separated combine. The separation of the basic mixture and the Additional gas is largely reversed, whereby the one to be withdrawn at one end of the cascade and the amount of additional gas to be supplied again at the other end can be significantly reduced.

A particularly useful embodiment for the parallel connection of several disconnection devices show F i g. 3 and 4. The lines 38 are for the common supply of four each slot-shaped nozzle channels arranged parallel to the lines 36 for the common discharge of the Core parts each made up of four (only two on the side boundaries of the arrangements) peeling channels. Two discharge lines each enclose a supply line and (except on the side Limitations) two feed lines each one discharge line. It then arises in the lateral Cross-section - as in FIG. 4 recognizable - that a device according to F i g. 1 mirror image of the channel is arranged consecutively to channel. The jacket parts of the gas pass through the lines 39 in Fig. 3 up and down. and are in a gas-tight housing which encloses the entire separation device and is not shown in the figure caught. They can be withdrawn from this housing via an attached pipeline will.

In one with an arrangement according to FIG. 1, the width of the nozzle 13 at the narrowest point was selected to be 0.23 mm and the inner radius of the baffle plate 11 to be 1.5 mm. A pressure of 80 Torr was maintained in the nozzle feed line 16, a pressure of 8 Torr in the suction line 19 and a pressure of 10 Torr in the suction line 17. A mixture of 95 mol percent He and 5 mol percent of a binary isotope mixture with an average molecular weight of about 350 was used

With a width of the peeling channel 15 of 0.18 mm, about 70% of the isotope mixture was withdrawn via the line 17 and 30% via the line 19. If the mole fraction of the light isotopic _component in lines 17 or 19 is denoted by η 1Ί or ra ₁₉ , then the separation in the usual definition resulted as an elementary effect

_ _{1 =} ο ₀₁₂

based on a mass spectrometric measurement.

Claims (7)

Patent claims: 1. Process for separating gaseous or vaporous substances with medium molecular weights over 200, especially isotopes, with different molecular weights and / or or different gas kinetic cross-sections, in which the mixture of nozzle-like Openings on peeling diaphragms, which they put in jacket parts and through the diaphragm openings behind breaking through core parts, flowing in and mechanically deflected in this way, characterized in that a lighter additional gas is added to the mixture and the jet emerging from the nozzle opens the path to the peeling diaphragm is deflected by less than 360 °. 2. The method according to claim 1, characterized in that that the addition of light gas is at least 1000 mole percent. 3. Device for performing the method according to claim 1 and / or 2, characterized through a central gas discharge line (19), one lateral end surface (12) of which at the same time has a Part of the nozzle channel (13) forms, while the opposite end surface as a peeling diaphragm (14) is formed, and by a curved baffle (11) that the nozzle channel (13) and the Peeling channel (15) connects. 4. Apparatus according to claim 3, characterized in that around a central nozzle (21) a mirror image of a gas discharge channel (26, 27) is provided to the side of the nozzle (21) and that the baffle plate (22) has the shape of a lying three and with its middle tip (23) is opposite the nozzle (21) (FIG. 2). 5. Apparatus according to claim 3, characterized in that the supply and discharge lines (38,36) are arranged parallel to one another so that a discharge line for four peeling channels as well as a supply line for four nozzle channels and the partition walls between the supply and discharge lines (38 and 36) on the front side as a baffle are formed (Fig. 3 and 4). 6. Apparatus according to claim 3 to 5, characterized in that the width of the nozzle (13 or 21) is kept smaller than 1 mm at its narrowest point. 7. Device according spoke 3 to 6, characterized in that the radius of curvature of the Deflection plate (11 or 22) in the area essential for beam deflection is smaller than 5 mm. 1 sheet of drawings 509 630/331 8.65 © Bundesdruckerei Berlin