DE1913098A1 - Floor tile for the absorption of backscattered and transmitted, low-energy X-ray and gamma rays - Google Patents

Description

Patent attorney Dipl.-Phys. Gerhard Liedl 8 Munich 22 Steinsdorfstr. 21-22 Tel. 29 84 62

B 4081

Giken Kogyo Kabushiki Kaisha, No. 3, Kioicho, Chiyoda-ku, Tokyo / JAPAN

Floor tile for the absorption of backscattered and transmitted, low-energy X-rays and gamma rays

The invention relates to a floor tile for the absorption of back-scattered, low energy x-rays and gamma rays.

Dr.D / sd

009815/1219

With the increasing use of x-rays and gamma rays in the In the broadest areas of application, e.g. in clinical and industrial areas, the risk of hitting people has also increased X-rays or gamma rays cause damage to health and genetic make-up. Because of this, various precautions have been taken taken to prevent x-rays or gamma rays from leaking out be emitted. The room in which X-rays or gamma rays are used is therefore used to prevent harm to third parties shielded. If, however, the ceiling, floor and walls are provided with a shielding device (in the following it is always referred to as `` Abschirmwändti and the like '), the X-rays and gamma-rays in the room in which they are being worked are partially reflected back. There is therefore a risk that the operators of the system will be hit by more x-rays or gamma rays than they are would be the case if there were no shielding walls or the like.

According to the present invention, a floor tile is now to be produced, the backscattered and transmitted, low-energy X-ray and absorbs gamma rays in order to achieve effective radiation protection for the people inside the shield.

This problem was solved by making this floor tile lead and

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Contains at least one substance which reduces the secondary emission of lead absorbed.

It preferably contains a filler of 70 to 90% by weight of a filler Lead compound, 5 to 25% by weight iron or an iron compound and 5 to 10% by weight of a calcium compound with a binder is blended from a synthetic resin, a plasticizer, a stabilizer and a lubricant so that the mixture obtained is as follows Has composition.

Synthetic resin 1.00 parts,
Filler 1.66-10.00 parts,
Plasticizer 0.16 to 0.41 parts,
Stabilizer "0.01 to 0.04 parts,

Lubricant 0.01-0.04 parts.

If X-rays or gamma rays with a frequency ν strike an atom of a substance whose electrons in the K-shell have a binding energy A, then if the energy h χ ν ( _n = Planck 'see constant) the X-ray or gamma quanta is greater than the binding energy A, an electron or electrons knocked out of the K-shell and the corresponding amount of energy is absorbed (K-absorption edge).

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Then the electrons of the L-shell, M-shell, N-shell etc. fall into the empty orbital of the K-shell, resulting in a line emission with the energies α., Oc ₂ , ß-p ß ₂ ^etc. The intensities of these emitted lines α, α ₂ , P ₁ , β ₂ etc. depend on the ratio of the statistical weights determined by the internal quantum numbers. In this way, the incident x-rays or gamma rays - depending on their energy - are absorbed by any of the K, L or w M shells of the substance atoms.

For example, with lead, X-rays or gamma rays with an energy which is greater than 83.95 KeV, which shows absorption in the K-edge leads to the emission of characteristic X-rays of 74.95 KeV (greatest statistical weight). This radiation leads to another Absorption in the L-edge and this in turn for the emission of characteristic X-rays with 14.76 KeV,

Iron, on the other hand, absorbs X-rays or gamma rays with a greater amount Energy than 7.11 KeV and emits a characteristic X-ray radiation with an energy of 6.40KeV.

Finally, calcium absorbs X-rays or gamma rays with a higher energy than 4.03 KeV and emits characteristic X-rays of 3.69 KeV.

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In addition to the photoelectric effects described above, the Compton effect occur. However, its relative proportion becomes very small when the energy of the primary X-rays or gamma rays decreases.

As the filler for the floor tile according to the present invention is preferably from 70 to 90 wt -.% Of a lead compound, 5 to 25 wt -.% Of iron or an iron compound and 5 to 10 wt -.% Of a calcium compound is experienced by X-ray or Gamma rays cause absorption in the K or L edge of the lead and are converted into characteristic X-rays of 14.76 KeV. This is converted by absorption in the K-edge of the iron into a characteristic X-ray radiation of 6.40 KeV and the latter into the characteristic X-ray radiation of calcium with 3.69 KeV, by absorption in its K-edge. Finally, the characteristic X-rays or gamma rays, the energy of which is equal to or less than 3.69 KeV, are absorbed by absorption in the M-edge of the binder used, as well as the lead, iron and calcium itself.

Also the Compton scattering caused by hitting the absorbent according to the invention Floor tile3 is created, is absorbed by the lead.

The floor tile made in accordance with the present invention has excellent properties Fire resistance, as a lead compound such as the one used

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basic lead carbonates with the binder even at a higher temperature does not burn. The floor tile also shows high mechanical strength and excellent chemical resistance.

Therefore, if a floor tile made according to the present invention is placed on the surface of a floor tile made of, for example, mortar or the like When installing the floor, the backscattered X-rays or gamma rays from the mortar or the like are strongly absorbed by the floor tile. The risk that the operating personnel located inside the shielding walls is exposed to radiation damage, becomes staik reduced. In addition, it is possible to easily define certain absorption properties for the backscattered radiation by using the floor tile, because the floor tiles in a factory in uniform composition and of uniform thickness are easy to manufacture. If you have a floor tile used according to the present invention, in which the proportion of filler is correspondingly increased in the mixture in relation to the binder, one can also achieve that the incident X-rays and gamma rays is absorbed. , The dose of X-rays or gamma rays on the surface of the soil is thereby diminished. Accordingly, the shielding effect can also be insufficient in itself The floor can be enlarged by gluing the floor tile.

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The following examples and the accompanying drawings serve as further information Explanation of the. Invention.

Show it:

1 shows a comparison between the energy spectrum in the diagram from rays backscattered from aluminum and the energy spectrum, which the backscattered rays provide when using a floor tile according to an embodiment of the present invention Invention sticks to aluminum;

2 shows in a diagram the ratio of the mass coverage per unit area of the filler to the scattering rate when used same embodiment;

3 shows in a diagram the ratio of the mass coverage per unit area of the filler to the lead equivalent thickness Use the same embodiment.

In the following, the invention is intended to be based on preferred embodiments to be discribed.

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Example I.

Basic lead carbonate 184 parts

(2 PbCO «χ Pb (OH) ₉ )

Iron powder 34, 5 parts

Calcium carbonate 11.5 parts

A filler having the above composition is uniformly mixed with a binder mixed and then shaped into a floor tile of a predetermined shape. The binder contains the following components:

Polyvinylchloride (synthetic resin)

Di-n-octyl phthalate (plasticizer)

chlorinated paraffin (plasticizer)

Lead stearate (stabilizer)

Dibutyl - tin stearate (lubricant)

An energy spectrum of the backscattered X-rays was determined as follows: The surface of a normal aluminum plate (350 mm χ 350 mm 15 mm, purity 99.99%) was over an area of 5 χ 5 cm irradiated vertically with X-rays of 70 KV tip spacing, 0.1 mA.

100 Parts 17th Parts 8th Parts 1, 5 parts 1, 5 parts

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The energy spectrum was measured at a scattering angle of 45 with a scintillation counter measured from NaJ (Tl) crystals and a 100-channel amplitude discriminator (TMC, Gammascope II, Model-102). Curve A in Fig. 1 shows the result. On the abscissa is the energy of the scattered back X-rays (in KeV) plotted the count rate of the backscattered X-ray quanta (in c.p.m. = counts per minute) on the ordinate. Will on the other hand, the floor tile produced by the method described above is glued to the surface of the normal aluminum plate and then from irradiated from the X-ray source, a different energy spectrum is obtained, which is shown in FIG. 1 as curve B, under the same measurement conditions. A Comparison of these curves shows that, with the exception of the neighborhood of 15 KeV (the characteristic X-ray radiation of lead), the backscattered X-rays are strongly absorbed. The mentioned "spreading rate" is defined as follows:

Counting rate of the X-ray quanta backscattered by a test plate (minus the background noise) _a

Counting rate of the X-ray quanta backscattered from a normal aluminum plate (minus the background noise)

Since this absorbent floor tile is lead - an excellent shielding material against rays - contains, X-rays or gamma rays are greatly weakened when penetrating the floor tile. Therefore one lets X-rays of 140 KV peak voltage, 0.18 mA on the surface of a normal lead plate (0.1 to 0.3 mm thick, purity 99.99%) stand out vertically and if it irradiates a field of 5x5 cm on the lead plate, you can

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Attenuation of the X-rays with an ionization chamber type dosimeter measure and use it to set up an attenuation curve for X-rays. The absorbent floor tile is then exposed to the X-rays and the corresponding lead equivalent thickness is obtained by interpolation from the attenuation curve for X-rays determined on the normal lead plate.

The embodiment described above is suitable for building materials because the basic lead carbonate with the polyvinyl chloride a plasticizer, a stabilizer and a lubricant at an elevated temperature does not burns.

If the floor tile according to the above embodiment has a thickness of 2 mm is produced, a nominal value of the backscatter rate of 18% is obtained and a lead equivalent thickness of 0.25 mm Pb.

example Π;

Basic lead carbonate 533, 6 parts

Iron powder 100 parts

Calcium carbonate 33.4 parts

⁴⁰⁸¹ 0098 15/12 19

100 Parts 20th Parts 10 Parts ι, , 5 parts ι, , 5 parts

A filler having the above composition is uniformly mixed with a binder mixed and then shaped into a floor tile of a predetermined shape. The binder contains the following components:

Polyvinyl chloride (synthetic resin) di-n-octyl phthalate (plasticizer) chlorinated paraffin (plasticizer) lead stearate (stabilizer) dibutyl tin dilaurate (lubricant)

In this embodiment, the floor tile has sufficient absorption capacity against transmitted radiation because it contains a higher proportion of filler relative to polyvinyl chloride. If they are in a thickness of 2 mm is produced, a nominal value of the backscatter rate of 18% and a lead equivalent thickness of 0.35 mm Pb are obtained.

The ratio of the mass occupancy per unit area and the scattering rate for the * absorbent floor tiles of Example I and Π is shown in FIG. The mass coverage per unit area (mg / cm) of the filler in
the tile is plotted on the abscissa and the scatter rate (%) on the ordinate. If the mass coverage per unit area of the filler contained in the tile is greater than 250 mg / cm, the dose will decrease! 0 0 9815 / 121S

scattered radiation essentially constant. If one also looks at the one that has passed through Radiation, it can be seen from FIG. 3 that the mass coverage per unit area of the filler and the lead equivalent thickness are proportional to one another are. The ordinate in FIG. 3 indicates the lead equivalent thickness (mm Pb), the abscissa the mass coverage per unit area (mg / cm) of the filler.

As the floor tile according to the present invention, both square

or rectangular individual pieces, as well as bahnförmi ge sections to understand.

4081

009 8 1 5V-'JT # i 9

Claims (6)

Claims ί 1. λ floor tile for the absorption of backscattered and durchgelac senen, low-energy X-rays and gamma rays, characterized in that it contains lead and at least one substance which absorbs the secondary emission of lead. 2. Floor tile for absorbing backscattered and transmitted, low-energy X-rays and gamma rays, characterized in that these floor tile a filler of 70 to 90 wt -.% Of a lead compound, 5 to 25 wt -.% Of iron or an iron compound and 5 to 10 Contains% by weight of a calcium compound which is mixed with a binder made of a synthetic resin, a plasticizer, a stabilizer and a lubricant in such a way that the mixture obtained has the following composition: Resin 1.00 parts Filler 1,66 to 10 parts Plasticizer 0.16-0.41 parts Stabilizer 0.01-0.04 parts Lubricant. 0.01 to 0.04 parts. 4081 009815/1219 3. Floor tile to absorb back-scattered and let-through, Low energy x-rays and gamma rays according to claim 2, characterized in that characterized in that the filler consists of 184 parts of basic? Lead carbonate, 34.5 parts of iron powder and 11.5 parts of calcium carbonate, and that the binder consists of 100 parts of polyvinyl chloride for the synthetic resin, 17 parts Di-n-octyl phthalate for the plasticizer, 8 parts chlorinated paraffin for the plasticizer, 1.5 parts lead stearate for the stabilizer and 1.5 parts Dibutyl tin dilaurate for the lubricant is composed. 4. Floor tile to absorb back-scattered and let-through, Low energy x-rays and gamma rays according to claim 2, characterized in that characterized in that the filler consists of 533.6 parts of basic lead carbonate, 100 parts of iron powder and 33.4 parts of calcium carbonate and that the Binder made from 100 parts of polyvinyl chloride for the synthetic resin, 20 parts of din-octyl phthalate for the plasticizer, 10 parts of chlorinated paraffin for the plasticizer, 1.5 parts of lead stearate for the stabilizer and 1.5 parts of di- . butyl tin dilaurate for the lubricant is composed. 009 815/1; 219 5. Floor tile to absorb back-scattered and let-through, Low-energy X-rays and gamma rays according to Claim 3, characterized in that the floor tile is produced with a thickness of 2 mm resulting in a backscatter rate of 18% and a lead equivalent thickness of 0.25 mm Pb can be achieved. 6. Floor tile for the absorption of backscattered and transmitted X-ray and gamma rays according to claim 4, characterized in that the floor tile is made in a thickness of 2 mm, whereby a backscatter rate of 18% and a lead equivalent thickness of 0.35 mm Pb can be achieved. 009815/12 19