DE3717047C1 - Thermoluminescence dosimeter for determining the skin dose - Google Patents

Abstract

An easily produced and rugged thermoluminescence dosimeter for determining the skin dose received by beta and gamma irradiation comprises a thin but mechanically reliable window membrane (6) of >/= 4 mg/cm<2> thickness, behind which a first TLD panel (3) of 5 to 25 mg/cm<2> thickness with high responsivity and based on Ca salt, a second TLD panel (4) of 50 to 150 mg/cm<2> thickness and a third TLD panel (5) of at least the thickness of the first TLD panel are arranged, one of the two latter panels being formed on the basis of Li or Be compounds and the other being formed on the basis of Ca salt and is equal to the first TLD panel in responsivity and energy-dependence. <IMAGE>

Description

The invention relates to a thermoluminescence dosimeter for determining the skin dose received by β- and γ- irradiation with three TLD disks of staggered thickness arranged behind one another behind a thin window film.

When handling radioactive substances, the skin dose has to be determined in certain cases. This is defined as the dose at a tissue depth of 70 µm. Measuring the skin dose is difficult with radiation, where the dose changes greatly depending on the depth of the tissue. This applies e.g. B. for low energy β radiation. To measure this radiation, an ideal dosimeter would have to consist of a tissue-equivalent, infinitely thin detector, which is covered in the radiation incidence direction with a tissue-equivalent layer of 70 µm thickness, and a tissue-equivalent backscatter would have to be attached behind the detector.

Such an ideal dosimeter is not possible bar. Existing dosimeters can be an ideal one Dosimeters only more or less well adapted be.  

The skin dose determination is particularly required for low-energy beta radiation, since for this radiation, when the body is irradiated from the outside, the dose decreases particularly sharply with increasing tissue depth, so that the basal layer of the skin is a critical organ. At the same time, the measurement of the skin dose is also particularly difficult in the case of low-energy β radiation, because of the large change in the dose with increasing depth in the tissue or in other materials. As a dosimeter to be as general as possible, be used in arbitrary radiation fields, a suitable dosimeter to determine the skin dose must not only β radiation of low energy, but β - and can also measure γ radiation energy independent as possible.

Four different types of dosimeters are known for dosimetry of beta radiation:

Dosimeter with a relatively thick detector,
Dosimeter with a thin detector and thin cover,
Dosimeter with several detectors arranged side by side and
Dosimeters with several detectors arranged one behind the other.

The present invention relates to the latter type. A dosimeter of this type is already described in DE-PS 31 00 868 by the applicant. This has an outer window film of ≲1 mg / cm ² thickness and then to the skin three congruent TLD panes of 15-30 mg / cm ² , 30-90 mg / cm ² and ≳90 mg / cm ² thickness.

This dosimeter according to DE-PS 31 00 868 allows an exact determination of the skin dose, and it additionally provides information about the course of the dose as a function of the tissue depth and thus rough information about the type of radiation. However, the use of this dosimeter in large quantities for personal dose monitoring is not without problems:
The very thin ≲10 µm window film proves to be extremely delicate during production, since it is particularly difficult to attach it to the rear wall or to mount the dosimeter glass. This is all the more important since the dosimeter holder must be renewed after each monitoring period and evaluation of the data obtained. Finally, the risk of damaging this thin window film when the dosimeter is worn is relatively high.

The aim of the invention is therefore a dosimeter, that is easy to manufacture and robust and the same monitoring of the personal dose at the same time comparable quality.

The thermoluminescence dosimeter according to the invention developed for this purpose is characterized by a thin but mechanically reliable window film of ≳4 mg / cm ² thickness, behind which a first TLD disk of 5-25 mg / cm ² thickness with a high response on a calcium salt basis second TLD disk of 50-150 mg / cm ² thickness and a third TLD disk of at least the thickness of the first TLD disk are arranged, the one of the last two disks based on Li or Be compound and the other on Ca -Salt base is formed and resembles in responsiveness and energy dependence of the first TLD disc.

The window preferably has a thickness of 7-10 mg / cm ² .

Other special features go from the Unteran sayings.

In this dosimeter, a mechanically insensitive window film is provided, the weight of which corresponds approximately to the tissue depth in which the dose is to be determined. For this reason, a TLD disk is provided immediately after this window, which is as thin as possible and can therefore approximately reflect the dose received in the depth range to be recorded. In order to compensate for the reduction in the evaluation signal associated with a reduced pane thickness, a TL salt-based disk (based on CaSO ₄ in polytetrafluoroethylene) is used for this purpose, which provides a particularly high luminous efficiency during the evaluation, so that the use itself the particularly thin TLD pane and relatively thick window film caused by the reduction in sensitivity is largely compensated.

However, such TLD disks based on CaSO ₄ do not register γ- radiation independently of energy, rather the light yield obtained in the evaluation for γ- radiation of low energy at the same dose is significantly higher than for hard γ- radiation. For example, 30 keV γ radiation at the same dose in the evaluation results in a signal 11 times higher than 1 MeV γ radiation.

In order to take account of this problem of the different γ sensitivity, the second or third TLD disk, and preferably the third one, is produced from the same or a material with the same sensitivity characteristic as the first disk. While a certain dose underestimation is possible with a second TLD disk based on CaSO ₄ in the evaluation due to the light yield obtained with special b / γ- mixed radiation fields, with a third TLD disk based on CaSO _{4, this is} all in rare cases Cases overestimated a small dose, which of course is more likely to be accepted.

The second TLD disk should then consist of a material that responds in an energy-independent manner, in particular a LiF material. This second disk should not be too thin, so that β- radiation of medium energy can only get insignificantly into the third TLD disk.

By means of the energy-independent registration of the q dose, a correction of this dose component can be achieved by means of the second disc and, on the other hand, based on the light yield of the second TLD disc, an approximate correction of the signal component due to lower getic β radiation can be carried out in the evaluation after irradiation will. This is always necessary if a certain proportion of soft β radiation is to be determined with a dosimeter that has a relatively thick window film, especially if it is ≳7 mg / cm ² thick.

The selection of the window film thickness, the thickness of the first TLD pane and the need for correction of the light yield achieved in the evaluation with the first TLD pane can be illustrated with the aid of FIG. 1. This shows the course of the relative dose rate depending on the tissue depth or layer thickness for relatively soft β radiation (from Pm - 147; E _{β max = 0.23 MeV). Particularly noteworthy in the curve as point "A" is the dose to be determined at a tissue depth of 7 mg / cm ² . Theoretically, the dose should be measured at this depth behind an ideal tissue-like film of 7 mg / cm ² thickness with an infinitely thin TLD disc. On the one hand, this is not possible and, on the other hand, it is not absolutely necessary, as can be seen from the drawing, since (for example with a TLD pane whose thickness and arrangement corresponds to the hatched area) the desired value can be obtained with sufficient accuracy by averaging. From this curve it follows that relatively thin first TLD slices are expedient with a relatively thick window, or else a corresponding correction must be provided in the evaluation, as can be easily read from the example in the drawing, after which a TLD -Width of about 5 mg / cm ² thickness behind an 8 mg / cm ² thick film only perceives a needful correction of the incident soft β radiation. This remainder, which is in need of correction, can be determined from the light yield of the first TLD disc after deduction of the dose component, which is due to hard β radiation and to γ radiation (determined using the third TLD disc, but corrected on the basis of the light yield of the second TLD disc). Pane) and the proportion attributable to medium-hard b radiation (can be determined using the corrected information of the second pane) and provided with the correction factor that takes account of the window thickness. A dosimeter with a cover of about 5 mg / cm ² thickness with a subsequent TLD disk appears to be particularly expedient, which can still register a substantial part of a low-energy β- radiation component, if present. A dosimeter according to the invention in the form of a finger ring dosimeter is indicated in FIG. 2: the first to third TLD disks 3, 4, 5 are located in a holder 1 of the ring 2 . A shrink film tube ( 6 ) is pushed over this arrangement and brought to firm contact by gentle heating. The window film 6 then had a thickness of 7 mg / cm ² . The first and third TLD discs 3 and 5 had a thickness of 10 mg / cm ² and consisted of CaSO 4 in poly tetrafluoroethylene. The second disc 4 had a thickness of 90 mg / cm ² and was made of LiF in polytetra fluorethylene. Instead of the TLD disk based on LiF, a TLD disk based on lithium borate (Li 2 B 4 O 7 ) or a material with the same detection characteristics as BeO can be used. In addition to the CaSO 4 mentioned above, a material based on CaF 2 can also be used for the first and third slices.}

Claims (4)

1. Thermoluminescence dosimeter for determining the skin dose received by β - and γ radiation with three TLD disks staggered congruently arranged one behind the other behind a thin window film, characterized by a thin but mechanically reliable window film ( 6 ) of ≳4 mg / cm ² thickness , behind which a first TLD disc ( 3 ) of 5 to 25 mg / cm ² thickness with high responsiveness based on Ca salt, a second TLD disc ( 4 ) of 50 to 150 mg / cm ² thickness and a third TLD Disc ( 5 ) of at least the thickness of the first TLD disc are arranged, wherein one of the last two discs is based on Li or Be compound and the other is based on Ca salt and in response and energy dependence of the first TLD Disc is equal. 2. Thermoluminescence dosimeter according to claim 1, characterized in that the window ( 6 ) has a thickness of 7 to 10 mg / cm ² . 3. Thermoluminescence dosimeter according to claim 1 or 2, characterized in that the first and third TLD disks ( 3, 5 ) are formed from CaSO ₄ in polytetrafluoroethylene, while the second TLD disk ( 4 ) consists of LiF in polytetrafluoroethylene. 4. Thermoluminescence dosimeter according to claim 3, characterized in that the window film ( 6 ) has a thickness of 7 mg / cm ² , and the first to third TLD discs have a thickness of approximately 10; 90 and 10 mg / cm ² .