DE1169041B - Ionization chamber dosimeter - Google Patents

Description

Ionization Chamber Dosimeter The invention relates to an as Pocket dosimeter suitable ionization chamber dosimeter for measuring radioactive levels Radiation dose received by the dosimeter wearer. With such For dosimeters, it is essential that their external dimensions are kept small can be. They consist of a sleeve in which a capacitor, an ionization chamber, a discharge electrode and a movable charging contact are housed. By The dosimeter's capacitor can close the charging contact for the purpose of charging with an external voltage source or for the purpose of determining the radiation dose depending on the degree of discharge with a sensitive voltmeter, e.g. B. connected to an electrometer.

While in some such dosimeters only the mutual capacitance of the ionization chamber electrodes is available as a capacitor, one of which, for. B. can be formed by the inner surface of the dosimeter sleeve, dosimeters are already known in which a wound capacitor is housed in the interior of the sleeve to increase the capacitance. In the known dosimeters of this type, the discharge space closes, i. H. the actual ionization chamber, to one end of the capacitor winding, whereby an unfavorable use of space, z. B. at a given capacity results in an undesirable increase in the external dimensions of the dosimeter.

The invention is based on the object of an ionization dosimeter, in its sleeve a wound capacitor, a discharge electrode and a movable one Charging contact is arranged, due to the shape of the capacitor, the location of the ionization chamber with respect to the capacitor and the construction and arrangement of the movable Make charging contact so that compared to the known Dosimetem an essential Saving space results and that the dosimeter without difficulty a badge-like Format can be given so that it is easily possible to use the sleeve as per already known, as an identification tag or as a carrier for the identification tag in addition to use.

The dosimeter according to the invention is characterized in that the capacitor wound on a conductive support tube and with its one document is conductively connected to this pipe, in which the actual ionization chamber forming cavity. from one side one on the bottom of the one with the other capacitor assignment Conductively connected sleeve attached flat electrode provided with a recess, from the other side one that engages in the recess in the deflected state the support tube inside touching leaf spring protrudes on a contact pin is attached, which is isolated by the bottom of a sleeve-like, in the Sleeve pushed in and at the same time sealing off the ionization chamber in a vacuum-tight manner Loading device is passed, the outwardly open cavity by means of a protective cover can be closed in a dust-tight and watertight manner.

In the drawing, an exemplary embodiment of the invention is shown schematically. It shows F i g. 1 shows a longitudinal section through the dosimeter, FIG. 2 shows a plan view of the dosimeter according to FIG. 1, FIG. 3 shows a longitudinal section through the capacitor of the dosimeter according to FIG. 1 along the line AB in FIG. 4 and FIG . 4 is a plan view of the capacitor of the dosimeter according to FIG. 1.

In FIG. 1 , the vacuum-tight flat sleeve 1 made of metal forms the ionization chamber 2 of the dosimeter. An outer surface 3 of the sleeve 1 serves as a support surface for receiving a micro-photo badge, not shown and serving as an identification tag. Two wire eyelets 4 are soldered on the outside of the sleeve 1 and hold the chain for carrying the dosimeter (see FIG. 2).

A flat inner electrode 6 , which is provided with a recess 7 , is fastened in the base 5 of the sleeve 1. The flat capacitor 8, which will be described in more detail later, is inserted into the sleeve 1. The capacitor 8 is designed in such a way that the plate-shaped inner electrode 6 protrudes into it when it is pushed into the sleeve 1. In addition, a loading bushing 9 , which in turn is sleeve-shaped and which at the same time forms the vacuum-tight closure of the ionization chamber 2, is inserted into the sleeve 1. The charging leadthrough 9 carries, electrically isolated from it, the electrically conductive leadthrough part 10, which continues on the one hand in the interior of the sleeve-shaped charging leadthrough 9 as a contact pin 11 and on the other hand in the interior of the ionization chamber 2 as a flat leaf spring 12, the latter in the capacitor 8 and in the recess 7 of the inner electrode 6 protrudes. A protective cover 13, which can consist of plastic, for example, is inserted into the sleeve-shaped charging bushing 9 to protect the contact pin 11 in a dust-tight and water-tight manner. A horseshoe magnet 14 is held on the outside of the dosimeter for measuring and is used to deflect the flat leaf spring 12 until it strikes the inner wall of a support tube 15 of the capacitor 8, which will be described in more detail later, and thereby creates a metallic and electrically conductive connection between the for measuring, but also for charging the capacitor 8, the contact pin 11 and the carrier tube 15 are produced.

In FIG. 4, the capacitor 8 is shown schematically. A metal foil 16 serving as an electrode is connected to the support tube 15 at a point 17 in a metallic, electrically conductive manner. The metal foil 16 and a second metal foil 18 are wrapped around the carrier tube 15 , the two metal foils 16 and 18 being insulated from one another by two insulating foils 19 and 20 which are made of plastic and serve as a dielectric. The outside, d. H. that is, the metal foil 18 that is finally wound onto the support tube 15 is connected with its outermost turn in a metallically electrically conductive manner to the inner wall of the sleeve 1 at a point 21.

The F i g. 3 shows that the two insulating foils 19 and 20 serving as dielectric are wider than the two metal foils 16 and 18 serving as electrodes; it also shows that the wider insulating foils 19 and 20 are arranged with respect to the two metal foils 16 and 18 in such a way that they protrude beyond the two metal foils 16 and 18 on both sides. If the capacitor 8 is inserted into the sleeve 1 , then only the end faces of the two insulating foils 19 and 20 can come into contact with the bottom 5 of the sleeve 1 , but not the end surfaces of the two metal foils 16 and 18. In a corresponding manner, the Insertion of the loading bushing 9, the end face 22 of which only comes into contact with the end faces of the two insulating foils 19 and 20, but not with the end faces of the two metal foils 1.6 and 18.

The F i g. 2 shows the arrangement of a photomicrograph 23, which contains the characteristic data of the person wearing the dosimeter, on the outer surface 3 of the sleeve 1 of the dosimeter. During manufacture, before the capacitor 8 is pushed into the sleeve 1, the outer metal foil 18, which was last wound onto the support tube 15 and which is longer than the other inner metal foil 16, is again C unwound so that the capacitor 8 has such a cross-section that it fits tightly into the sleeve 1 by suction. As a result, the capacitance of the capacitor 8 is not changed, because this is given solely by the length of the inner metal foil 16 that is wound up first, in this respect. than the outer metal foil 18 then still has a length which is at least as great as that of the inner metal foil 16.

The protective cover 13 is provided with a recess 24 into which the contact pin 11 protrudes. An end face 25 of the protective cover 13 facing the charging bushing 9 serves as a stop and, when the protective cover 13 is pushed into the sleeve-shaped charging bushing 9, rests against its case base 26 .

The sleeve 1 is made of metal, preferably made of a low atomic material (Z <10). As a sleeve material, only metal fulfills the requirement that the display of the dosimeter should be independent of the ambient conditions (such as, for example, air pressure, temperature and humidity), i.e. H. the requirement that the ionization chamber 2 should be made vacuum-tight. Low-atomic material for the production of the sleeve 1, as well as a suitable dimensioning of the latter, ensure that the dependence of the dose display on the quantum energy of the radiation between about 50 keV and 5 MeV is insignificant for the measurement accuracy. However, it is entirely possible to choose what is known as a tissue-equivalent material as the ionization chamber material. But since, as already said, only metal is possible as a material for the sleeve 1 , the walls of the ionization chamber would have to be made of tissue-equivalent material in such a way that the sleeve 1 made of metal is provided on the inside with a coating of tissue-equivalent material or a A second inner sleeve made of this material, which then forms the actual ionization chamber, is inserted into the outer sleeve 1 made of metal.

Instead of air, a tissue-equivalent gas, for example Nitrogen or argon can be used.

The insulator 27 between the charging bushing 9 and the bushing part 10 consists of glass or an equivalent material, for example ceramic or quartz. These materials ensure the required vacuum-tight closure of the ionization chamber 2.

The insulating foils 19 and 20 are made of a plastic that has both a high insulation resistance (> 1020 9 - cm) and radiation resistance, which ensures that the insulating properties of the insulating foils 19 and 20 are not significantly weakened by the effects of radiation (reduction at most approx 1: 10) and also very quickly returns to its original state (approximately within 24 hours).

The ionization chamber 2 of the dosimeter can also be filled with a compressed filling gas. For this purpose, the sleeve 1 of the dosimeter is provided with a filling nipple which is preferably arranged on the end face forming the base 5 of the sleeve 1 in such a way that it opens into the ionization chamber 2 in the base 5. If the eyelets 4 are now attached to this end face of the sleeve 1 , as is appropriate (cf. FIGS. 1 and 2), then one of them can be designed so that it serves as a closure for the filling nipple.

The flat dosimeter according to the invention allows in an advantageous manner Way the immediate reading of the respective irradiation, but without practical completely sufficient measuring properties to be significantly larger or a different one To have the format like a normal dog tag, which is therefore cheaper Way to combine.

Claims (2)

Claims: 1. Ionization chamber dosimeter, in the sleeve of which a wound capacitor, a discharge electrode and a movable charging contact are arranged, characterized in that the capacitor (8 ) is wound onto a conductive support tube (15) and one of its occupations is conductive with this tube is connected, in the cavity forming the actual ionization chamber from one side a flat electrode (6) attached to the bottom of the sleeve (3) conductively connected to the other capacitor occupancy and provided with a recess (7 ), from the other side an electrode (6) In the recess (7) engaging, in the deflected state the support tube (15) inwardly touching leaf spring (12) protrudes, which is attached to a contact pin (11) - which is isolated by the bottom (22) of a likewise sleeve-like, in the sleeve (1) inserted and at the same time the ionization chamber (2) vacuum-tight closing loading device ( 9) is passed, the outward h can be closed in an open cavity by means of a protective cover (13) in a dust-tight and watertight manner. 2. Dosimeter according to claim 1, characterized in that its sleeve (1) has a badge-like format, is provided with eyelets (4) for attaching a carrying chain and also serves as an identification tag or as an identification tag carrier. 3. Dosimeter according to claim 2, characterized in that the capacitor (8) is formed in that metal foils (16, 18) serving as electrodes are wound onto the carrier tube (15 ) with the interposition of insulating foils (19, 20) serving as a dielectric are, the inner, first wound metal foil (16) with its innermost turn with the carrier tube (15) and the outer, last wound metal foil - (18) with its outermost turn with the sleeve (1) are metallically and electrically connected. 4. Dosimeter according to claim 3, characterized in that the insulating foils (19, 20) wider than the metal foils (16, 18) and with respect to the latter are arranged such that they protrude on both sides over the metal foils (16, 18) and with its one end face when the capacitor (8) is pushed into the sleeve (1) a stop on the bottom surface (5) of the sleeve (1) and with its other end face a stop when the loading bushing (9) is pushed into the sleeve (1) on the end face (22) of the loading passage (9) . 5. Dosimeter according to claim 4, characterized in that the insulating foils (19, 20) consist of a plastic which has both a high insulation resistance (> 1020 9 - cm) and a high radiation resistance. 6. Dosimeter according to claim 5, characterized in that the outer metal foil (18 ) wound up on the support tube (15) is unwound again so far before the capacitor (8) is inserted that the capacitor (8) is sucked tight fits into the sleeve 1. 7. Dosimeter according to one of claims 2 to 6, characterized in that the protective cover (13) is provided with a recess (24) into which the contact pin (11) protrudes, and that one of the loading duct (9) facing end face (25 ) of the protective cover (13) serves as a stop and rests on the case base (26) of the loading passage (9) . 8. Dosimeter according to one of claims 2 to 7, characterized in that the sleeve (1) made of metal, preferably made of a low-core material (Z <10) . 9. Dosimeter according to claim 8, characterized in that the wall thickness of the sleeve (1) is dimensioned such that the dependence of the dose display on the quantum energy of the radiation between about 50 keV and 5 MeV is insignificant for the measurement accuracy. 10. Dosimeter according to one of claims 2 to 9, characterized in that the walls of the ionization chamber (2) consist of a tissue-equivalent material. 11. Dosing device according to claim 10, characterized in that the tissue-equivalent material is applied as a coating on the inner surfaces of the sleeve (1) made of metal. 12. Dosimeter according to claim 10, characterized in that the walls of the ionization chamber (2) are formed by a second inner sleeve which is pushed into the outer sleeve (1) made of metal. 13. Dosimeter according to one of claims 2 to 12, characterized in that air is used as the filling gas. 14. Dosimeter according to one of claims 2 to 12, characterized in that a tissue-equivalent gas, for. B. nitrogen or argon is used. 15. Dosimeter according to one of claims 2 to 14, characterized in that the - insulator (27) between the loading bushing (9) and the bushing part (10) made of glass or an equivalent material, for. B. ceramic or quartz. 16. Dosimeter according to claims 13 and 14, characterized in that a gas-tight closable filling nipple is provided on the dosimeter and the dosing device is filled with compressed filling gas via it. 17. Dosimeter according to spoke 16, characterized in that the filling nipple on the bottom (5) of the sleeve (1) forming the end face of the sleeve (1) is arranged such that it opens into the ion! -Sationskanuner (2). 18. Dosimeter according to one of claims 2 to 17, characterized in that the eyelet or eyelets (4) is or are attached to the end face of the sleeve (1) forming the base (5). 19. Dosimeter according to one of the Ansprache16 to 18, characterized in that the eyelet or one of the eyelets is designed as a closure of the filling nipple. Considered publications: German Patent Nos. 674 051, 935 387, 962 005; German Auslegeschrift No. 1 044 293; British Patent No. 734 314.