DE1056287B - Geiger-Mueller counter tube - Google Patents

Description

The invention relates to a Geiger-Müller counter tube for a large intensity range of γ and / or ^ radiation, with electrodes arranged concentrically in the common discharge space.

ß- and / or y-radiation can currently be measured over a large intensity range by scintillation counters, ionization chambers, proportional counters or by the usual Geiger-Müller counters filled with halogen gas (self-extinguishing) in connection with electronic circuits. Scintillation counters, ionization chambers and proportional counters work satisfactorily, but they are costly when used in conjunction with counting circuits because of the large number of facilities required. Conventional Geiger-Müller counters filled with halogen gas and operating in parallel can be used satisfactorily, but difficulties may arise because the counters may not retain their original characteristics. If the meter characteristics change or if a meter fails, incorrect results are delivered. The counters operated in parallel and filled with halogen gas are advantageously used for transportable devices, since the operating voltage can be kept relatively low and the corresponding counting circuit is considerably less complicated and cheaper than for the other chamber or counter systems mentioned.

Meters filled with halogen gas have the opposite of conventional meters filled with organic gas the advantage that their service life is not affected by the counting process; also is the The operating voltage is lower and the extinguishing agent is not used up during the counting process. at low counting rates can be counted and displayed by a counting circuit will. At high counting rates (e.g. over 60,000 pulses per minute), an average current value occurs, and if the radiation density is even higher, the mean current flowing through the tube is a measure of the Density of radiation .. The mean current changes over an intensity range of at least 50: 1 like the logarithm of the radiation density, and with a very high radiation density the mean one decreases Current down to a saturation value. This is the average current for operating a practical display device is sufficient (e.g. 50 μΑ), the physical size of the counter must be kept small. A counter of the usual dimensions and cylindrical shape (i.e. the sensitive length at least twice the cathode diameter), which is sensitive to lower radiation densities a low saturation current, and the saturation occurs with a radiation field of medium Density one. If the counter size is reduced, Geiger-Müller counter tube

Applicant:

Atomic Energy of Canada Limited,
Ontario (Canada)

Representative: Dr. K. Sdiwarzhans, patent attorney,
Munich 19, Romanplatz 9

Claimed priority:
V. St. v. America August 1, 1955

Ivan Landen, Fowler
and Lynn Alexander Keeling Watt,
Deep River, Ontario (Canada),
have been named as inventors

the saturation current increases and so does the intensity of the radiation field required for saturation. For example, a counter with a Diameter of 19 mm and a length of 38 mm a saturation current of only a few μΑ, and the Saturation occurred at a radiation intensity of approximately 1 r / h. Another meter with 6.35 mm Diameter and 25.4 mm length had a saturation current of 20 μΑ, when compared to the first Counter double load resistance. The saturation took place at a radiation field of approximately 10 r / h. A third meter, 1.58 mm in diameter and 15.87 mm in length, had a saturation current of 50 μΑ, the load resistance being greater than that of the second counter, and saturation occurred at about 50 r / h. In the presently used designs it is therefore necessary to have two or more Use counters of different sizes in parallel with suitable counting circuits to cover a large area the radiation densities.

A counter tube is known in which the outer electrode is surrounded by the glass body of the counter tube is composed of frustoconical parts arranged one behind the other, identically designed. A however, such a counter tube cannot cover a large intensity range.

Furthermore, a counter tube is already known, the outer electrode of which is outside the counter tube glass body consists of several isolated, cylindrical parts of different diameters. -

90S'508 / 358

Claims (3)

In a measuring arrangement, either one or the other Tedl of the outer electrode is connected to voltage. - Errors due to changes in the respective counter tube characteristics cannot be avoided. The present invention is based on the object of creating a counter which has the same advantages as conventional Geiger counters connected in parallel, while avoiding the disadvantages which arise when several counters are connected in parallel. The counters should respond to both ß and / radiation, with the sensitivity to ß and / rays extending over a wide range that can be determined in advance. The single counter according to the invention should be just as effective as two or more conventional counters connected in parallel. The invention consists in that, as is known per se, the distance between the electrodes in the longitudinal direction of the counter tube continuously decreases in value towards one end of the counter tube, the electrodes each consisting of one piece or of several separate but electrically connected parts. This arrangement offers a large counting range and adequate measurement sensitivity for low radiation intensities, and at the same time a part or parts are provided with a smaller volume and with a small electrode spacing, which results in a high average current when measuring high radiation intensities. Furthermore, the sensitivity of the arrangement is greatly increased without the sensitivity being significantly changed. The cathode of the counter tube according to the invention advantageously forms part of the gas-tight tube wall, and if sensitivity is desired, the cathode can be provided with an entry window at the end. The counter tube is preferably filled with halogen gas, but another suitable gas filling can also be used. The Eirfindung is explained in more detail with reference to the drawing. 1, 2 and 3 show schematic representations of the counter tube shapes according to the invention, in which the cathode is designed so that there are different distances between the cathode and anode Anode is designed so that there are different distances between cathode and anode, FIG. 7 shows another embodiment of the counter tube according to the invention, sections of the cathode being electrically isolated from one another, and FIG. 8 shows a circuit diagram for the counter tube shown in FIG. Each of the counting tubes shown in FIGS. 1 to 6 has a gas-tight tubular cathode 10 which is provided with an entry window 11 and an inlet 12 for the anode 13. In the case of the counting tubes according to the invention, the distance 14 between the outer surface of the anode 13 and the inner surface of the cathode 10 along the anode 13 changes significantly. According to FIG. 1, the inner surface of the cathode 10 has a conical shape for this purpose. According to FIG. 2, the cathode tail 15 adjoining the window 11 is conical, while the cathode part 16 is cylindrical. According to FIG. 3, the cathode 10 has two cylindrical inner surfaces 17 and 18 with different diameters, the surface 17 with the larger durometer adjoining the window 11. If desired, the outer surface of the cathode 10 can be designed to correspond to its inner surface, so that the cathode wall remains the same thickness. The cathode 10 can consist of pressed Bleah. 4, 5 and 6, the inner surface of the cathode 10 is cylindrical, while the surface of the anode 13 is shaped so that the distance 14 between the surface of the anode 13 and the inner surface of the cathode 10 near the window 11 is substantially greater as near the introduction 12. For this purpose, as shown in FIG. 4, the surface of the anode 13 is conically shaped. However, as shown in FIG. 5, only the part 20 of the anode 13 closest to the window can be conical, while the remaining part of the anode 13 is cylindrical. The counter tube shown in FIG. 6 has an anode with two cylindrical parts 21 and 22 of different diameters, the cylindrical part with the smaller diameter being located next to the window 11. In Fig. 7 a further embodiment of the counting tube according to the invention is shown, in which the sections 23 and 24 of the cathode are separated from one another by an insulator 25 so that balancing resistors 26 and 27 (Fig. 8) can be switched into the separate cathode circuits, whereby a Fine adjustment of the overall characteristics of the counter tube and its associated circuit is possible. The counting tubes according to the invention can be produced in the usual way. The / ^ window is not necessary for / radiation and can be omitted. However, it can be retained and used to calibrate the instrument if a built-in / J source is used, which can be shielded by a shutter that is customary for / measurements. The size of the meter depends on the usual type of construction, depending on the application for which the meter is intended. The size of a meter according to the invention for a particular application is given below, for example: Sensitive total length 44.44 mm, the diameter of the cathode at the entrance window being 22.22 mm and tapering over a length of 31.7 mm to 9.5 mm in diameter ; it is followed by a cylindrical section with a 9.5 mm Durohmesser and 12.7 mm length. This meter has a cylindrical anode with a diameter of 0.51 mm and is operated with 480 + 20 volts. Patent claims: 1. Geiger-Müller counter tube, for a large intensity range of / - and / or / ^ - radiation, with electrodes arranged concentrically in the common discharge space, characterized in that that, as is known per se, the distance between the electrodes is continuous in the longitudinal direction of the counter has decreasing values towards one end of the counter tube, the electrodes each from one piece or from several separate, but electrically permanently connected parts exist. 2. counter tube according to claim 1, characterized in that the inner surface of the outer electrode or the surface of the inner electrode from the entry window of the counter tube towards the other end of the counter tube tapers conically, while the counter-elitrode is cylindrical. 3. counter tube according to claims 1 and 2, characterized in that the conical u