DE2239065A1 - IONIZATION CHAMBER - Google Patents

Description

"Ionization chamber"

The invention relates to an ionization chamber, in particular an air-equivalent ionization chamber.

In air-equivalent ionization chambers, the walls, which can also form the electrodes, are made of a material whose mean atomic number is approximately the same as that of the air filling the chamber (approx. 7> 4-), so that the chamber opens ionizing radiation is similar to how air responds. Such ionization chambers can be used, for example Use a medical x-ray source intensity measurement. The walls and electrodes can be made out Plastic, e.g. made of methyl methacrylate. Since the latter material electrically insulates, must if the material as If the electrode is to be used, an electrically conductive coating should be provided, e.g. through a thin coating of graphite can be formed in colloidal porm.

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The atomic number of graphite is "6. This has a large X-ray energy, for example at 200 keV to 1.25 MeV, has only minor effects. However, it was found that at lower energies the thickness of the graphite layer has a critical influence on the sensitivity of the Chamber can be. In particular, it has proven difficult to find identical chambers with the same sensitivity to produce at low energies, since the thickness of the graphite coating is a critical influencing factor and it it is difficult to maintain the same thickness from chamber to chamber.

The invention is based on the object of specifying an ionization chamber which can be easily manufactured in such a way that that the electrical properties are the same from chamber to chamber. The invention is based on an ionization chamber from whose effective cavity is enclosed by a wall made of electrically insulating material, which consists of a covering has electrically conductive material; and solves the problem on which it is based in that the electrically conductive Covering is designed as a pattern of strips that take up only a small proportion of the surface of the wall.

In a preferred embodiment, the new ionization chamber comprises two spaced apart Disks made of insulating material, between which and insulated from which a third disk of the same Material is arranged. The first two disks form the polarization electrodes of the ionization chamber, while the third disc represents the collector electrode. As an isola-

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A particularly suitable material is methyl methacrylate. In a further development of the invention, both surfaces are the middle Disc and the inner surfaces of the other two discs each with an electrically conductive coating in the form of a Pattern of thin concentric and radial stripes that cross each other like a spider web and to which the usual electrical connections can be made. The electrically conductive strips can, for example by engraving the pattern with a sharp tool and filling in the engraved recesses with a conductive Material such as colloidal graphite. However, there are other ways of manufacturing of the pattern in question.

It was surprisingly found that the small Conductive areas formed by the strips are sufficient to polarize the chamber to saturation and collect the entire ionization current.

Since the narrow strips only take up a small proportion of the surface of the electrodes, e.g. only 6% Sensitivity fluctuations from chamber to chamber due to an uneven thickness of the conductive coating only go back to the small proportion of the covering on the surface and therefore only correspondingly small be. .

The electrical connection to the strip patterns can, for example produced by means of a conductive coating, which is applied outside the stripe pattern is and is in contact with it. This conductive

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lag should not be applied to the wall delimiting the effective cavity of the ionization chamber, otherwise the advantage that can be achieved with the invention is partially would be lost again.

The invention is particularly useful for air equivalents Ionization chambers suitable, but it can also be used with other ionization chambers whose walls are made of insulating material, e.g. in tissue-equivalent chambers. Nor is it necessary that the chamber have a has a flat cylindrical shape.

The invention is explained with further advantageous ones Details based on a schematically illustrated embodiment. In the drawings show:

Pig. 1 shows a longitudinal section through an ionization chamber according to the invention,

FIG. 2 shows a plan view of a polarization electrode of the ionization chamber according to FIG. 1,

Fig. 3 is an electrical circuit diagram of a circuit in which the ionization chamber according to FIG. 1 is operated.

The air-equivalent ionization chamber shown in Fig. 1 comprises two disks 1 and 2 made of methyl methacrylate, the are attached to the two opposite ends of a flat cylindrical housing 3 made of aluminum. A third

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Plate 4 made of methyl methacrylate is in the middle between the discs 1 and 2 by means of rings 5, 6, 7 and 8 from the same material attached. The disk 4 is in an annular shape, formed between the rings 6 and 7 Pinched recess. ! Compressible O-Binge 9 represent the sufficient rigidity of the arrangement. For protection, polyethylene rings 10 are attached to both ends of the chamber. The housing 3 is provided with a filter opening 11 through which, in view of the fact that the entrances 5 "to do not form a complete seal, atmospheric air can enter the chamber.

The two cavities 12 and 13 formed between the disks 1 and 4 or 2 and 4 represent the effective or active cavity of the chamber. It can be seen that the entire wall delimiting the effective cavity the chamber is made of methyl methacrylate.

The disk 4 forms the collector electrode of the chamber. the inner surfaces of the discs 1 and 2 form the polarization electrodes of the chamber. Both surfaces of the disc 4 and the inner surfaces of the discs 1 and 2 are provided with an electrically conductive coating or coating, of which Shape is shown in Fig. 2. Fig. 2 shows the disc 1 or 2, but it is similar to a spider web Patterns of stripes 14 also on both surfaces of the disc. In the illustrated embodiment, the pattern comprises eight concentric circles, the diameter of which increases from 1 cm to 8 cm, and also, as shown, radial ones Stripes. The strips are produced in such a way that, by means of a sharp tool, the cross-section is approximately V-shaped.

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formed pits approximately 0.25 mm wide and 0.25 mm deep and the pits with colloidal graphite fill out. The electrical connection to the strip pattern is made by means of an annular graphite coating 15 that touches the outer concentric ring of the stripe pattern. The resistance between the innermost Ring and lining 15 is approximately 100 kjb; this value however, it is not critical, nor is the pattern of the stripes. Other suitable stripe patterns can easily be found determine experimentally.

From Fig. 1 it can be seen that the pads 15 on the Disks 1 and 2 are in electrical contact with housing 3; the corresponding, but narrower pads 15 on the disc 4- are by means of a contact piece 16 and a wire 17 with the inner pin of a triaxial Connector 18 connected, the outer wall of which is attached to the housing 3. Between those representing the polarization electrodes Disks 1 and 2 and the disk 4- representing the collector electrode, a protective ring is provided, by a graphite coating 19 on the adjoining surfaces of the rings 5 and 6 or 7 and 8 in connection with annular recesses 20 is formed between these two pairs of rings. One possibly from disks 1 and 2 over Leakage current flowing on the surface of the rings 5 and 8 is therefore diverted to the linings 19. The pads 19 are connected to the middle contact of the plug by means of contact pieces 21 and wires 22.

Fig. 1 shows the ionization chamber approximately on a 1: 1 scale. The disks 1 and 2 have a diameter of approx.

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about 11.4 cm and 4 mm thick, while the disc is 4 is approximately 1 mm thick. The effective cavity of the ionization chamber has a diameter of approximately 7/6 cm and the distance between the disks 1 and 4 or 2 and 4 is 1.2 cm, so that the entire effective cavity (12 + 13) approximately 108 cm ^ tall. .

The ionization chamber is connected to a metal housing 24 by means of a three-axis cable 23 (see FIG. 3), which contains the associated electrical circuit. The conductive coatings or stripes on the panes 1 and 2, the polarization electrodes, are above the outer one Head of the cable 23 is connected directly to the metal housing 24. The disc 4, 'the collector electrode, is over the innermost conductor of the cable with the input terminal of a conventional one that is fed back via a resistor Operational amplifier 25 connected, its output signal is displayed by a measuring instrument 26. The operational amplifier 25 is in a metallic shielding housing

27 housed, with the protective rings 19 and also the ground input terminal over the middle conductor of the cable of the operational amplifier are connected. The polarization voltage for the chamber is made by means of a DC-DC converter 28 generated, which the shielding case 27 and thus the amplifier 25 and the Disk 4 at a positive potential of + 150 V opposite the housing 24 and the disks 1 and 2 holds. The converter

28 becomes from a power supply unit 29 connected to the network fed, which also supplies the supply voltage for the operational amplifier 25.

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In the ionization chamber described, the strips 14 take up an estimated only 6 % of the total area surrounding the effective cavity of the chamber. It was found that the response behavior and sensitivity of this chamber to X-rays differ from 58 keV to 1.25 MeV and at 32 keV from chamber to chamber by a maximum of 5 %.

EXPECTATIONS:

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Claims (6)

Expectations Ό J ionization chamber, the effective cavity of which is a wall made of electrically insulating material is enclosed, which has a covering made of electrically conductive Material, characterized in that the electrically conductive coating as a pattern of Strips (14-) are formed, which take up only a small proportion of the area of the wall (1, 2, 4 ·, 5-8). 2) ionization chamber according to claim 1, characterized in that they are two at a distance from each other located disks (1, 2) made of insulating material comprises as polarization electrodes, between and insulated from them a third disk (4) made of the same material is arranged as a collector electrode. 3) ionization chamber according to claim 2, characterized in that the three discs (1, 2, 4) from Consist of methyl methacrylate. 4) ionization chamber according to claim 2 or 3j thereby characterized in that both surfaces of the central disc (4) and the inner surfaces of the other two Discs (1, 2) each with an electrically conductive coating Ί O <) »00/0920 1A / G-41 780
- ί - in the form of a pattern of thin concentric and radial strips (14) are provided to which the usual electrical connections can be produced (Fig. 2). 5) ionization chamber according to claim 4, characterized in that the electrically conductive strips (14) by engraving the pattern with a sharp tool and filling the engraved depressions with a conductive one
Material are generated. 6) ionization chamber according to one of claims 1 to 5 »
characterized in that the electrically conductive coatings consist of colloidal graphite. 3 Π 9 H 0 H / ü ¹ J 2 M. Le ers ei \ e