DE1016855B - Process for the production of closed radioactive preparations - Google Patents

Description

Process for the production of closed radioactive preparations The invention relates to a method for the production of closed radioactive preparations. Such preparations are known to have the shape of tubes, spheres, beads, plates or other bodies in or between which the radioactive emitter is enclosed is.

The question of what material these carrier bodies or sheaths are made of for the emitter are for hard, gamma-emitting radioactive substances easy to solve. Since the rays have a great ability to penetrate one, such as B. is common with radium, even use platinum-iridium as the shell material. If we stick to the example of radium and make the requirement, apart from the hard gamma rays to let the soft gamma rays or beta rays penetrate to the outside, and although with as large a fraction of their intensity as possible, then relate The wrapping material presents difficulties that can only be remedied by compromises permit.

Some contradicting demands are made of the shell material: 1. The shell material must be mechanically stable, that is, have great strength.

2. The envelope must be as high as possible for radiation of the type mentioned Grade be permeable.

3. The casing material must be corrosion-resistant to the greatest possible extent be.

4. The shell material must be resistant to prolonged exposure to radiation.

5. In the case of beta-emitting preparations, the envelope wall should be designed in this way be that as little bremsstrahlung as possible is generated in it.

For the stated purpose will. today around the world in prevalent Scope Monel metal, which is an alloy of nickel and copper, is used. Monel metal has a specific gravity of about 9, and its strength is so great that In the technically important cases, material thicknesses of 0.1 to 0.2 mm are sufficient. Using thinner membranes is practically only possible in exceptional cases, namely when there is no mechanical stress. _ The absorption effect a monel layer 0.1 mm thick is by no means negligible. as An example is given that the hard beta radiation of the radiovttrium with 2.2 MeV max is already weakened by half by a monel layer of 0.1 mm a monel layer of 0.2 mm but loses three quarters of its original intensity.

In some special cases, attempts have already been made instead of Monel metal aluminum or duralumin should be used. A use of aluminum however, to a larger extent is never an option, since aluminum is resistant to chemical influences is way too vulnerable. Just think about that there are traces of mercury that are always present in laboratories, are already sufficient for rapid oxidation to bring about the aluminum with the oxygen in the air. In addition, there is the impossibility To solder aluminum.

The importance of the chemical resistance of the envelope of a radioactive The preparation must not be underestimated under any circumstances. For example, it corrodes in the case of a medicinal radium supplement, the coating over the years, so may due to emitted emitter substance considerable damage to the attending physician and arise in the patient. In addition, the loss would be considerable material Values connected. Thought has also been given to using plastics as wrapping material to use.

With regard to corrosion resistance, strength and radiation permeability the required conditions are met. Plastics, however, are long continuous irradiation is completely destroyed and cannot be used for this reason.

It has now been found that for wrapping radioactive preparations titanium and titanium alloys are particularly suitable. It's free from the disadvantages described above.

Titanium has roughly the strength of steel and a resistance to corrosion, which are larger than stainless chromium-nickel steels with regard to certain chemicals is. A particular advantage for the purpose according to the invention is the small density of titanium. It is 4.5 g / ccm and is therefore only half as high as in the case of steel or the Monel metal listed above. As an example, that a membrane of 0.1 mm titanium reduces the beta radiation of the radioyttrium by only 25% weakens, compared to 50% of a Monel metal membrane of the same thickness.

From these contexts the progress, the means the use of titanium metal as a wrapping material for radioactive materials.

The idea of the invention can be applied to all that occur in practice Forms of radioactive preparations such as tube preparations, plate preparations, spherical preparations among others, apply. The titanium casing according to the invention - is radioactive for everyone Suitable for spotlights. Preferably beta emitters and weak gamma emitters, like strontium, thulium, thallium, also cesium, but also thought of alpha emitters.

It is not only thought that the whole shell for the preparation is uniform to manufacture from titanium metal. Rather, it can be advantageous, and it certainly is within the scope of the invention, for example, only the membrane through which the radiation should emerge from titanium, but the remaining parts of the preparation envelope from others To manufacture materials - such as brass, nickel, Monel metal - or also particularly strongly absorbing materials - such as silver, platinum or gold - or from ferromagnetic materials other than nickel - e.g. B. iron or cobalt or the like - to manufacture. It is also possible to use ceramic materials here.

It goes without saying that those known from titanium processing Treatment methods of titanium can also be used here. For example it is possible that a molded part or turned part made of pure titanium in the annealed state produced and then hardened again by one of the known methods becomes, be it by treatment with a gas at elevated temperature, resulting in a Hardening (for example nitride formation), or mechanical influences. The welding and soldering processes otherwise used for titanium should also be used here can find. In particular, the coating of the titanium metal is important at the soldering points, before soldering with other metals. This can be, for example done by the fact that the titanium metal in the melts of salts of the concerned Metals is immersed. Titanium metal can be combined with a firmly adhering tin, Plating a silver or copper layer if you have previously melted it in tin. Dipping silver or copper chloride (or other chlorides).

According to the invention, the use of titanium metal is not only intended to the immediate encasing of the radioactive substance must be restricted. It should of course also be possible to make the radioactive emitter substance through several partition walls To delimit titanium metal or its alloys from the exterior. each of these Partition walls can be an independent structural element, for example is thought that the radioactive emitter was housed in a cylindrical tube whose cylindrical envelope surface is made of titanium metal, and that such Tubes in a spherical or cylindrical sleeve, also made of titanium metal can be made, is inserted. The outer sleeve can be the tube Enclose tightly or include an air space between the sleeve and the emitter tube. For example, the outer shell can have a clear diameter of 5 to 6 mm, the Tubes, on the other hand, have an outside diameter of 2 mm. Need it here too not both construction elements are made of titanium metal, rather it can For example, the immediate shell of the source preparation is made of Monel metal but the outer sleeve, for example any applicator, made of titanium metal exist.

The outer sleeve, such as the applicator, does not need exclusively to be made of titanium metal. It can also be a grid-like construction element made of titanium can be used, for example, surrounded by a plastic layer or is covered by a plastic or other layer. This element can serve to center and hold the radioactive elements.

It should also be noted that, for example, with radioactive Gold the actual radiator does not need a special cover, but without further ado can be used in an applicator.

About a radioactive preparation, its covering in whole or in part Made of titanium metal, to seal, you do not necessarily have to solder or welding. There is definitely the possibility of taking the preparation through Gluing or cementing to seal that radioactive substance does not get into the outer space can get. It is also possible to use organic putties or adhesives To use material if you make sure that alpha resp. Beta radiation does not or penetrates only strongly weakened to the cement or adhesive point. This can be achieved by placing an absorbent layer between radioactive substance and Putty or glue joint switches on, through which the radiation is significantly weakened or is completely absorbed. It is also possible through appropriate kon. Structural design to place the glue points in the penumbra.

The last-mentioned construction principle is of general importance and not limited to radioactive preparations, their wrapping material in whole or in partly made of titanium metal or its alloys. It's not open either Beta emitters limited, also for low or large gamma emitters This design principle is important to wavelength.

Claims (12)

PATENT CLAIMS: 1. Process for the production of closed radioactive preparations, characterized by the use of titanium metal or its alloys as a cladding material for the radioactive source. 2. Procedure according to claim 1, characterized in that the casing for the preparation is uniform is made of titanium metal. 3. The method according to claim 1, characterized in that that a casing for source preparations made from the usual materials, for example Monel metal is made in the areas where the radiation is supposed to escape Titanium is made. 4. The method according to claim 3, characterized in that the material ceramic materials are used for the preparation coating. 5. Procedure according to Claim 1, characterized by the use of titanium metal or whose Alloys for the production of further casings in which the encapsulated source preparation Takes place. 6. The method according to claim 5, characterized by cylindrical Tubes made of titanium metal, which are inserted into spherical or cylindrical bodies are. 7. The method according to claim 1 or 5, characterized in that the radiator preparations can be used with play in the further cover. B. Method according to claim 1 or 5, characterized in that the outer shell is any applicator. 9. A method according to claim 1 or 5, characterized in that an lattice-like construction element made of titanium is used, which is the centering or holder of the radioactive elements is used and, for example, from a plastic layer is surrounded or covered with such. 10. The method according to claim 1, characterized characterized in that the immediate envelope of the source preparation by gluing or cement is sealed so that radioactive substance does not get into the outside space can get. 11. The method according to claim 10, characterized in that the construction is made so that alpha or beta radiation through an absorbing layer or significantly weakened between the radioactive substance and the cement or adhesive point is absorbed. 12. The method according to claim 10, characterized by a construction, where the glue point is in the penumbra of the radiation.