DE1286649B - Radioactive source of radiation - Google Patents

Description

permeability are met. For such wrappings, io product made of glass as the parent substance. At the hearth are designed as cylindrical tubes, this ceramic product are made of a position

various metals, including B. iron, cobalt, nickel, and ceramic materials mentioned. Similar notices can be found on page 128 of the 1958 volume of the journal »Nucleonics«.

It is also known from German patent specification 600 991, Porcelain masses in unfired and unglazed state to mix with radioactive substance and burn the whole thing on it and Powder is added to this a corresponding amount of cobalt in the form of cobalt oxide and then the crystallized (devitrified) form. It is achieved that the cobalt is extremely fine in this product is distributed, up to an atomic order of magnitude, in such a way that it is a real one Is part of the crystal lattice of the product. The active form is generated by irradiation

G
to glaze. This method has the disadvantage that the product in which the cobalt-59 is converted to cobalt-60

an exact dosage of the content of radium is not possible because during the burning process with the at temperatures required for this, part of the radium evaporates.

The thought of putting the radioactive material in an as Embed the ceramic base body is also based on the published documents of the German Patent application A 21548 VIIIc / 21g known, according to which as a carrier body for the radioactive substance Carbon, preferably graphite or activated carbon, is used or the carrier body should consist of a mixture of carbon and ceramic and glassy substances.

The invention is based on the object of providing a radioactive radiation source for very specific applications, namely to develop for conditions under which they are at high temperatures in corrosive atmosphere is exposed to particularly high mechanical loads. For example the radiation source should be able to be embedded in a zinc oxide briquette to enable it to pass through to pursue an oven. Another area of application is the measurement of the burn-off of the walls of ceramic stoves. The known radiation sources cannot be more satisfactory for these purposes Use wisely, since the material in which the actual active substance is embedded is not the necessary one Has or is unable to withstand mechanical stress to withstand high temperatures, especially in a corrosive atmosphere.

In the radiation source mentioned at the outset, this object is achieved in that according to the invention the cobalt 60 atoms are components of a degassed titanium glass free of potassium and sodium.

The invention further provides that the devitrified titanium glass is arranged in a container made of stainless steel is, which in turn is surrounded by a shell made of sintered aluminum oxide with a Also made of sintered aluminum oxide, the plug is closed, which is attached to the shell is welded on. Such a radiation source is produced according to the invention in FIG is converted. So there is a much wider distribution down to the atomic order of magnitude than with the known radiation sources, in particular those described in the Belgian patent. The selection of such a ceramic product leads to not inconsiderable advantages, which are shown below summarized are:

1. High mechanical, chemical and thermal resistance which the use for the mentioned cases allowed,

2. the ability to set the high melting point exactly what determines the exact one The point of decay of the radiation source at a certain temperature is useful, for example is important for determining the wear and tear of the refractory material in a blast furnace is,

3. high resistance to nuclear radiation (the product according to the present invention resists the radiation emitted by the cobalt-60 atoms),

4. The radioactive cobalt-60 atoms are completely retained in the compound as they are part of the crystal lattice of the devitrified mass and not, as with the known ones Radiation sources added to or embedded in the masses.

Exemplary embodiments of the invention are shown in the drawing. Show it

F i g. 1 and 2 sectional views of two embodiments, wherein the radiation source according to FIG. 1 to determine the wear and tear of the refractory Lining a blast furnace is suitable, while the radiation source according to FIG. 2 particularly suitable for measuring the thickness of a glass sheet during cooling,

F i g. 3 schematically shows a system for controlling the thickness of a glass sheet during manufacture Use of the radioactive radiation source according to FIG. 2 and

F i g. 4 the application of a radiation source according to

Way that the sintered alumina plug using a high 65 glass of the present invention is sensitive to the measurement of a con melting point and a high content of silica vektionsgasstromes.

and aluminum oxide at a temperature of about At the radiation source according to FIG. 1 forms the

1100 ⁰ C is welded onto the shell. radioactive substance part of the cylinder 2 from

3 4

a ceramic product with the following layers of the blast furnace and a radiation exposure: source according to FIG. 1 (with a thickness in the size

AOQoi order of one or a few millicuries) in each of these

yy os 40 / insert holes, whereupon these with a ramming mass

Q οίο / ^{5 made of} carbon or a refractory cement

p} * ο / ι <ςο / ° be closed. The other layers of the fire

^{cou Z4)} oil l ° solid linings are manufactured normally.

The product corresponds to that in example 94 of a radiation source according to FIG. 1 is at a

French patent 1177 799 described. refractory lining with a thickness of 70 cm

The cobalt-59 changes strongly under the neutron io (e.g. from silica and aluminum oxide)

radiation in a nuclear reactor in radioactive enough to be carried outside the blast furnace with a

Cobalt-60 µm, the radiation preferably being detected using a radiation detector, e.g. B.

occurs when the cylinder is made from the product of a Geiger-Müller counter or a scintillation

located in a tube 3 made of stainless steel. counter.

The product does not contain potassium or sodium, 15 The refractory lining will wear out

since these two alkali metals are strongly activated by the fact that the detector uses the

would if the product is found to activate the disappearance of the radiation source,

Cobalt-59 to Cobalt-60 in a nuclear reactor which coincides with the disappearance of them

is located. bearing stone takes place (a radiation source of

The radiation source is constructed as follows: The 6 millicurie can still be determined from the product through a 75 cm thick outlet 2, which allows the radioactive subclothes to pass through). The ray dance contains, is in a tube 3 made of stainless steel source dissolves in part (tube 3 and plate 4 made of rust housed. This is steel cut off by a plate 4) in the cast iron and partly in the closed by a bead 3a of the tube 3 slag.

is held. The tube 3 is located in a loading 25 The advantages of a radiation source according to the invention

container or a shell 5 made of sintered aluminum manure when determining the wear and tear of the fire

oxide that is produced by a lining of a blast furnace made of the same material is essentially

standing stopper or stopper 6 is closed, the borrowed the following:

at 7 to the container 5 using a the radiation source that holds in the blast furnace

Glass with a high melting point with a content of 30 prevailing high temperatures;

of more than 50% silica and more than 30% aluminum - it withstands the high mechanical loads

minium oxide and lime at a temperature of from, which result from the deformation that

1100 ° C is welded on. The welding by means of which the stone in which it is housed undergoes;

Special glass is made in such a way that the radioactive substance contained in the stone

one first a slurry of the glass powder 35 does not diffuse into the neighboring stones, which the

in a very pure, completely scorching or making finding easier.

evaporating oil in the form of a thick paste. 2 shows a radiation source which

represents. The joint 7 is coated with this paste in a manner similar to that of FIG. 1 is formed, but others

between the stopper 6 and the container 5 and has dimensions and one of the stopper 6

the radiation source, in particular the paste, has while 40 carried holding rod 6a . The dimensions

7 to 10 minutes at a temperature of 1100 ^° C. The radiation source of FIG. 2 is in millimeters

The boiling oil causes the following to warm up:
giving aluminum oxide what the self-diffusion

of the aluminum oxide from the glass into the to be connected ^ f ⁰ SJ; ^des ^ ^ν ™ «Ζ 6

the end of the parts and vice versa, so that an extensive 45 diameter ™ * cylinder 2 6

drawn connection is created. When the pipe is heated -Length 3 .. 8

for a period of less than 7 minutes, the diameter of the pipe 3 is 8

the risk that the quality of the weld will be un- i; ^an ^ ^{des ßel} ™ ^te " ⁵ .:, · · ·" f0

is sufficient. Container diameter 5 18

The radiation source according to FIG. 1 the following 50 diameters the rod 6a 2

Have dimensions in millimeters: The radiation source of Fig. 2 is particularly for

α ύ ν α or »Determination of the thickness of a glass panel at the exit

Length of the cylinder 2 20 of _a manufacturing furnace for the purpose of automatic

Diameter of the cylinder 2 3.2 suitable for regulating the thickness of the panel. Such a one

External height of the pipe 3 30 device is shown schematically in FIG. 3 shown on

Outside diameter of the pipe 3 8 _{wdcher maQ dag end deg} ^^ _{8 gje} | _{dag dje}

Length of the container 5 with stopper 6 42 contains glass mass 9, from which a table 10 with the help

Outer diameter of the container 5 12 _{the same in the direction of the arrows / rotating}

The radiation source according to FIG. 1 is drawn for different roles 11 and 12. The glass sheet 10 for purposes of use in a corrosive atmosphere 60 is found at the moment of its formation at a high temperature, in particular for the temperature of the order of 1100 to measurement of the wear of refractory linings - 1600 ⁰ C and in an atmosphere 13 which is corrogenic by blast furnaces. contains ding gases whose temperature is between

You can z. B. is about 1200 and 1300 ⁰ C when repairing a blast furnace.

drilling in certain stones with a carborundum with comparable The 65 carried by its rod 6 a radiation source 14 designated tool about 10 mm deep holes, in accordance with F i g. 2 withstands this high temperature and its diameter between 9 and 15 mm is corrosive atmosphere and allows in the future, and so about a hundred holes in several co-operation with the radiation detector 15 (Geiger-

Müller counter or scintillation counter), which feeds a known electronic unit 15a, the Determine the thickness of the panel 10 immediately after it is formed so that if the thickness changes the board the rollers 11 and 12 can be given the correct speed without delay. Through this control an incorrect thickness of the glass sheet is avoided, which would inevitably occur when the determination the thickness would be a certain distance from the exit from the bath.

Another application of a radioactive radiation source according to the invention is shown in FIG. 4 shown, which shows how the velocity of a convection gas flow in a brought to high temperature closed vessel can be measured, e.g. B. to the effect of carbonic acid gas on graphite determine which one is brought to a very high temperature (especially in a heterogeneous, with Graphite temperate and carbonated gas cooled nuclear reactor).

For this purpose, a graphite block 17 can be placed in a container 16, which is heated to z. B. 1000 ⁰ C is brought.

The container 16 is arranged in a vessel 19 in which a water stream 20 flows. The flow of the carbonic acid gas contained in the container 16 takes place in the direction of the arrows F around the cylinder 21, which forms a deflector, and the speed of the convection flow of the carbonic acid gas is determined by means of a small screw 22 which can be rotated about a vertical axis and which is driven by the carbonic acid gas flow in the direction of the arrow F _{1 is set} in rotation, a radiation source 23 according to the invention being attached to a wing of this screw. This radiation source interacts with a radioactivity detector 24, the pulses of which are counted by a known electronic arrangement 24a, a collimator 25 being provided in front of the detector 24 so that the radiation source 23 only affects the detector when it reaches the bore 25a of the Collimator 25 is opposite. This allows the minute speed of the screw 22 and thus the speed of the convection current to be easily determined (either through the calculation or preferably through a previous calibration).

A radioactive source according to the invention can have numerous applications of measurements or determinations in corrosive atmospheres and / or at high temperature. You can z. B. by means of such a radiation source the path of a zinc ore briquette in a vertical Track what the determination of the mean residence time of such a briquette in the zinc furnace Furnace as well as the instantaneous speeds of the briquette at different points.

For this purpose, a radioactive radiation source according to the invention is arranged in the middle of the briquette, and their path is followed by means of a radiation detector arranged inside the furnace, what is made possible that the radiation source according to the invention the temperature of 1200 ° C and the can withstand a highly corrosive atmosphere (e.g. containing volatile chlorides) in the furnace.

Claims (3)

Patent claims: 1. Radioactive radiation source for use under strong mechanical stress high temperature and / or in a corrosive atmosphere, the radioactive cobalt-60 atoms contains, characterized in that the cobalt 60 atoms are components of a degassed titanium glass free of potassium and sodium. 2. Radioactive radiation source according to claim 1, characterized in that the devitrified titanium glass is placed in a stainless steel container, which in turn is made of a shell sintered aluminum oxide is surrounded, which is also made of sintered aluminum oxide existing stopper is closed, which is welded onto the shell. 3. A method for producing a radioactive radiation source according to claims 1 and 2, characterized in that the stopper made of sintered aluminum oxide using a glass with a high melting point and a high content of silica and aluminum oxide at a temperature of about HOO ⁰ C on the envelope is welded. 1 sheet of drawings